聚苯胺热掺杂十二烷基苯磺酸的反应过程及其结构

与传统的质子酸掺杂相比，采用具有功能性的两亲大分子对聚苯胺（PAN）掺杂，可以使产物的加工性和稳定性大大提高［1～3]．十二烷基苯磺酸（DBSA）是研究得比较多的掺杂酸之一，其掺杂过程一般都采用辅助溶剂，由此而引起PAN与DBSA结合程度低、掺杂效率低、溶剂需后处理?..

热迁移掺杂浓度分布的测量

本文介绍了一种热迁移掺杂后形成的片状掺杂区纵向浓度分布的测量方法，并实际测量了约１０００微米范围内的浓度分布。对计量公式和测量误差也给了较为详细的推导和分析。实测发现热迁移掺杂后反型层的杂质浓度基本上是一恒量。

氧化-热活化氮掺杂改性活性炭吸附金-硫代硫酸根络离子

硫代硫酸盐法是最有可能取代氰化法的浸金方法,但活性炭不能有效吸附Au(S_(2)O_(3))^(2-)_(2),使得硫代硫酸盐浸金法难以得到工业应用。为提高活性炭对Au(S_(2)O_(3))^(2-)_(2)的吸附效果,采用氧化-热活化氮掺杂法对活性炭改性,H_(2)O_(2)为氧化剂,三聚氰胺与氨水为氮源,热活化制备出不同的氮掺杂活性炭。采用Boehm滴定法和X射线光电子能谱(XPS)分析了活性炭表面含氧酸官能团含量、元素含量及官能团种类。结果表明,氧化活性炭过程中,在H_(2)O_(2)的浓度为4 mol/L,温度为55℃下改性1 h,活性炭表面酸性官能团含量为0.70574 mmol/g。在热活化氮掺杂过程中,三聚氰胺的掺杂效果高于氨水,三聚氰胺用量为0.016 mol/L,室温掺杂4 h,且在900℃下热活化2 h所得的活性炭对Au(S_(2)O_(3))^(2-)_(2)的最大吸附量为547.12μg/g,热活化氮掺杂活性炭表面负载吡咯氮显著提升了其对Au(S_(2)O_(3))^(2-)_(2)的负载量。

用石墨做电热器的热迁移掺杂设备

本文叙述了用石墨做电热器热迁移掺杂设备的研制,给出了温度梯度的控制方法,同时对石墨电热器的实际效果进行了小结。

掺杂硅热压工艺烧结制备Ti_2AlC陶瓷材料

以Ti、TiC、Al为原料,采用热压工艺制备出相组成为Ti2AlC块体材料。合成材料的X-射线衍射和扫描电镜(SEM)分析的结果表明:当烧结温度为1400℃时,材料中的主晶相为Ti2AlC,为10μm大小的板状多晶体;而在1500℃的温度下烧结所得材料的主晶相为Ti3AlC2,其板状多晶体的晶粒尺寸平均约为20μm。掺加硅时,随着温度的提高有利于Ti3AlC2的生成。

磺酸掺杂煤基聚苯胺/HDPE导电复合材料的制备研究

煤基聚苯胺 (CBP)是一类有着广阔应用前景的导电填料。本文用热掺杂法制得DBSA掺杂态CBP ,并采用熔融共混工艺 ,制备出HDPE/CBP DBSA导电复合材料。结果表明 :70℃下退火2h ,DBSA :CBP =1 6 (质量比 ) ,该条件下电导率为 0 179s/cm ;红外光谱说明DBSA对CBP起到了较好的掺杂作用。复合体系中CBP -DBSA含量为 13%时 ,复合材料的电学。

碳纳米管和碳黑掺杂对RDX激光点火特性的影响

采用光声光谱技术和差示扫描量热法研究了碳纳米管(CNTs)和炭黑(CB)掺杂对黑索今(RDX)激光点火特性的影响。结果表明:纯RDX在368mJ激光作用下,没有发生明显变化。经CNTs和CB掺杂处理后,RDX样品在很小的激光能量作用下就会发生分解,CNTs掺杂比CB掺杂对RDX的激光点火特性影响显著,在223mJ二者掺杂都存在一个最佳的点火延滞期。DSC分析表明掺杂后影响了RDX的热分析性能。

Sn掺杂Ge-Sb-Te相变薄膜的晶化特性

用磁控溅射法制备了掺杂Sn的Ge_2Sb_2Te_5相变材料薄膜,研究了Sn含量对结晶性能的影响.薄膜的X射线衍射(XRD)表明,热处理使薄膜发生了从非晶态到晶态的相变,并出现Sn-Te相.通过示差扫描量热(DSC)实验测出在不同加热速率下非晶态薄膜粉末的结晶峰温度,计算了材料的结晶活化能.根据结晶动力学分析和结晶活化能数据,掺杂Sn后的Ge-Sb-Te具有更高的结晶速率,用于光存储时将具有更高的擦除速度.

High sensitivity detection of baicalein by N,S co⁃doped carbon dots and their application in biofluids

In this work,p⁃phenylenediamine and L⁃cysteine were used as raw materials,and water⁃soluble N,S co⁃doped carbon dots(N,S⁃CDs)with excellent performance were prepared through a one⁃step solvothermal method.The morphology and structure of N,S⁃CDs were characterized by transmission electron microscope,X⁃ray diffrac⁃tion,Fourier transform infrared spectroscopy,and X⁃ray photoelectron spectroscopy,and the basic photophysical properties were investigated via UV⁃Vis absorption spectra and fluorescence spectra.Meanwhile,the N,S⁃CDs have excellent luminescence stability with pH,ionic strength,radiation time,and storage time.Experimental results illus⁃trated the present sensor platform exhibited high sensitivity and selectivity in response to baicalein with a detection limit of 85 nmol·L-1.The quenching mechanism is proved to be the inner filter effect.In addition,this sensor can also detect baicalein in biofluids(serum and urine)with good accuracy and reproducibility.

Synthesis,characterization and gas-sensing properties of Pd-doped SnO_2 nano particles

SnO2 nano particles with various Pd-doping concentrations were prepared using a template-free hydrothermal method.The effects of Pd doping on the crystal structure,morphology,microstructure,thermal stability and surface chemistry of these nano particles were characterized by transmission electron microscope,X-ray diffractometer and X-ray photoelectron spectroscope respectively.It was observed that Pd-doping had little effect on the grain sizes of the obtained SnO2 nano particles during the hydrothermal route.During thermal annealing,Pd-doping could restrain the growth of grain sizes below 500℃ while the grain growth was promoted when the temperature increased to above 700℃.XPS results revealed that Pd existed in three chemical states in the as-synthesized sample as Pd^0,Pd^2＋ and Pd^4＋,respectively.Pd^4＋ was the main state which was responsible for improving the gas-sensing property.The optimal Pd-doping concentration for better gas-sensing property and thermal stability was 2.0%-2.5% （mole fraction）.

Microspheres of graphene oxide coupled to N-doped Bi_2O_2CO_3 for visible light photocatalysis

Hierarchical microspheres of a graphene oxide（GO） coupled to N‐doped（BiO）2CO3 composite（N‐BOC‐GO） was synthesized by a simple hydrothermal approach. The N‐BOC‐GO composite gave enhancement in photocatalytic activity compared to the pure BOC and N‐BOC samples. With 1.0wt% GO, 62% NO removal was obtained with N‐BOC‐GO. The factors enhancing the photocatalytic performance were the high electron‐withdrawing ability and high conductivity of GO and improved visible light‐harvesting ability of N‐BOC‐GO with a 3D hierarchical architecture due to the surface scattering and reflecting（SSR） effect. An effective charge transfer from N‐BOC to GO was demonstrated by the much weakened photoluminescene intensity of the N‐BOC‐GO composite. This work highlights the potential application of GO‐based photocatalysts in air purification.

Preparation, characterization and electrochemical properties of boron-doped diamond films on Nb substrates

A series of boron-doped polycrystalline diamond films were prepared by hot filament （HF） chemical vapor deposition on Nb substrates. The effects of B/C ratio of reaction gas on film morphology, growth rate, chemical bonding states, phase composition and electrochemical properties of each deposited sample were studied by scanning electron microscopy, Raman spectra, X-ray diffraction, microhardness indentation, and electrochemical analysis. Results show that the average grain size of diamond and the growth rate decrease with increasing the B/C ratio. The diamond films exhibit excellent adhesion under Vickers microhardness testing （9.8 N load）. The sample with 2% B/C ratio has a wider potential window and a lower background current as well as a faster redox reaction rate in H2SO4 solution and KFe（CN）6 redox system compared with other doping level electrodes.

Si-doped diamond films prepared by chemical vapour deposition

The effects of Si doping on morphology, components and structure characteristics of CVD diamond films were studied. Si-doped CVD diamond films were deposited on Si substrate by adding tetraethoxysilane （TEOS） into acetone as source of reactant gas. The morphology and microstructure of diamond films were characterized by scanning electron microcopy （SEM）. The crystalline quality of diamond films was studied by Raman spectroscopy and X-ray diffractometry （XRD）. The surface roughness of the films was evaluated with surface profilometer. The results suggest that Si doping tends to reduce the crystallite size, enhance grain refinement and inhibit the appearance of （11 I） facets. Raman spectra indicate that Si doping can enhance the formation of sp2 phase in diamond films. Moreover, Raman signal of SiC was detected, which suggests the existence of Si in the diamond films. Smooth fine-grained diamond （SFGD） film was synthesized at Si to C ratio of 1%.

Effect of Mg doping on electrochemical performance of Li_3V_2(PO_4)_3/C cathode material for lithium ion batteries

Li3Mg（2x）V（2-2x）（PO4）3/C（x=0,0.05,0.1,0.2） composites were synthesized by carbothermic reduction,using a self-made MgNH4PO4/MgHPO4 compound as Mg-doping agent.X-ray diffraction（XRD）,scanning electron microscope（SEM）,electrochemical performance tests were employed to investigate the effect of Mg doping on Li3V2（PO4）3/C samples.The results showed that a proper quantity of Mg doping was beneficial to the reduction of charge transfer resistance of Li3V2（PO4）3/C compound without changing the lattice structure,which led to larger charge/discharge capacity and better cycle performance especially at high current density.Li3Mg（2x）V（2-2x）（PO4）3/C sample with x=0.05 exhibited a better performance with initial charge/discharge capacity of146/128 mA·h/g and discharge capacity of 115 mA·h/g at 5C,while these two figures were 142/118 mA·h/g and 90 mA·h/g respectively for samples without Mg doping,indicating that a proper amount of doped Mg can improve the electrochemical performance of LVP sample.All of these proved that,as a trial Mg dopant,the synthesized MgNH4PO4/MgHPO4 compound exhibited well doping effect.

Hydrothermal synthesis and enhanced photocatalytic activity of hierarchical flower-like Fe-doped BiVO_4

Fe-doped BiVO4with hierarchical flower-like structure was prepared via a hydrothermal method using sodium dodecylbenzene sulfonate(SDBS)as structure directing agent.X-ray diffraction(XRD),scanning electron microscope(SEM),transmissionelectron microscope(TEM),high resolution transmission electron microscope(HRTEM),X-ray photoelectron spectroscopy(XPS)and UV-Vis were applied for characterization of the as-prepared samples.The formation mechanism of flower-like structure wasproposed based on the evolution of morphology as a function of hydrothermal time.Fe-doped into substitutional sites of BiVO4effectively improved the migration and separation of photogenerated carrier and enhanced the utilization of visible light.Flower-likeFe-doped BiVO4showed much higher visible-light-driven photocatalytic efficiency for degradation of methyl blue compared withthe pristine BiVO4.And the sample with a Fe/Bi mole ratio of2.5%showed the highest photocatalytic efficiency.

In situ synthesis of Fe-N-C catalysts from cellulose for hydrogenation of nitrobenzene to aniline

Owing to Fe being the most abundant and least expensive transition metal on the earth,the utilization of Fe-based catalysts for catalytic hydrogenation has attracted worldwide attention.In this work,a series of N-doped C supported Fe catalysts(Fe-N-C)were prepared by co-pyrolysis of cellulose and ferric chloride under ammonia atmosphere.Characterization methods such as elemental analysis,atomic absorption spectroscopy,nitrogen adsorption-desorption isotherms,transmission electron microscopy,high-resolution transmission electron microscopy,X-ray diffraction,and X-ray photoelectron spectroscopy were carried out to explore the physicochemical properties of the catalysts.Using hydrogenation of nitrobenzene as a model reaction,the catalysts prepared at different pyrolysis temperatures displayed different activities.Fe-N-C-700 exhibited the best activity among these catalysts,with the yield of aniline being up to 98.0%under 5 MPa H2 at 120℃ after 12 h.Combined with the results of catalyst characterization and comparative tests,the transformation of Fe species and the generation of N-doped C,especially graphitized N-doped C,in the catalyst may be the main factors affecting the activity.A kinetic study was carried out and the apparent activation energy was obtained as 31.53 kJ/mol.The stability of the catalyst was also tested and no significant decrease in the activity was observed after 5 runs.

Crystallization Behavior and Properties of B-Doped ZnO Thin Films Prepared by Sol-Gel Method with Different Pyrolysis Temperatures

Boron-doped zinc oxide transparent （BZO） films were prepared by sol-gel method. The effect of pyrolysis temperature on the crystallization behavior and properties was systematically investigated. XRD patterns revealed that the BZO films had wurtzite structure with a preferential growth orientation along the c-axis. With the increase of pyrolysis temperature, the particle size and surface roughness of the BZO films increased, suggesting that pyrolysis temperature is the critical factor for determining the crystallization behavior of the BZO films. Moreover, the carrier concentration and the carrier mobility increased with increasing the pyrolysis temperature, and the mean transmittance for every film is over 90% in the visible range.

Effects of heat treatment conditions and Y-doping on structure and phase transition temperature of VO2 powders

The VO2 powders were prepared by hydrothermal synthesis.The effects of heat treatment conditions and Y-doping on the structure and phase transition temperature of VO2 were studied.The XRD,SEM and TEM results show that the heat treatment temperature has a significant effect on the crystal transformation of VO2 precursor.Increasing temperature is conducive to the transformation of precursor VO2(B)to ultrafine VO2(M).The Y-doping affects the structure of VO2.Y^3+can occupy the lattice position of V4+to form YVO4 solid solution,which can increase the cell parameters of VO2.Due to the lattice deformation caused by Y-doping,the aggregation of particles is prevented,and the grain is refined obviously.DSC curves show that Y-doping can reduce the phase transition temperature of VO2(M).After adding 9 at.%Y,the phase transition temperature can be reduced from 68.3 to 61.3℃.

C-I codoped porous g-C_3N_4 for superior photocatalytic hydrogen evolution

Porous C‐I codoped carbon nitride materials were synthesized by in‐situ codoping with iodized ionic liquid followed by post‐thermal treatment in air.The effects of doping content of C‐I codoping with different amounts of ionic liquid on the structural,optical and photocatalytic properties of the samples were investigated.Characterization results show that more compact interlayer sacking can be achieved by post‐thermal treatment.Combined with C‐I codoping by insertion of ionic liquids,much enlarged surface area but optimized sp2 conjugated heterocyclic structure can be found in the catalysts.Optical and energy band analysis results evidence that the light absorptions especially in visible light region are significantly improved.Although the band gap of porous C‐I codoped samples enlarge because of the generation of porous,the negatively shifted conduction band position thermodynamically supplies stronger motivation for water reduction.Photoelectricity tests reveal that the photo‐induced electron density was increased after C‐I codoping modification.Also,the recombination rate of electron‐hole pairs is remarkably inhibited.The catalysts with moderate C‐I codoing content perform sharply enhanced photocatalytic H2 evolution activity under visible light irradiation.A H2 evolution rate of 168.2μmol/h was achieved and it was more than 9.8 times higher than pristine carbon nitride.This study demonstrates a novel non‐metal doping strategy for synthesis and optimization of polymer semiconductor with gratifying photocatalytic H2 evolution performance from water hydrolysis.

Ordered mesoporous Sn-SBA-15 as support for Pt catalyst with enhanced performance in propane dehydrogenation

A series of Sn‐incorporated SBA‐15materials with high specific surface areas and highly orderedmesoporous structures were synthesized by a facile one‐pot method and used as catalyst supports.A reference sample was also prepared using a conventional impregnation method.The catalystswere characterized using various methods,and their activities in propane dehydrogenation wereinvestigated.The incorporation of Sn into the SBA‐15matrix led to strong interactions between Snspecies and the support,and these helped to maintain the oxidation states of Sn species during thereaction.Substitution with Sn changed the interfacial properties of the Pt species and improved thefunction and effect of the Sn promoter.The catalytic activities and stabilities of the Pt catalysts supportedon Sn‐incorporated SBA‐15were better than those of the impregnated sample.However,thecatalytic performance deteriorated when an excessive amount of Sn was introduced and the interactionsamong Pt,Sn species,and the support became weaker.The Pt/0.5Sn‐SBA‐15catalyst gavethe best propene selectivity,i.e.,98.5%,with a corresponding propane conversion of about43.8%.