碳纳米管阵列的气相沉积制备及场发射特性

运用酞菁铁热解法气相沉积制备了碳纳米管阵列.所得碳纳米管呈多壁结构.单根碳纳米管的平均直径约为25 nm，长度约4～5 μm，且具有很好的准直性.研究了碳纳米管阵列的平面场发射特性，相应的开启电压和阈值电压分别为1.28和2.3 V•μm－1，表明碳纳米管具有很强的场发射能力.利用场发射显微镜观察了碳纳米管阵列的场发射像，发现碳纳米管阵列的场发射主要集中在样品薄膜的边缘部位.这是由于碳纳米管密度过大而产生的屏蔽效应所致.     

Tunable Photoluminescence Across the Entire Visible Spectrum from Carbon Dots Excited by White Light

Although reports have shown shifts in carbon dot emission wavelengths resulting from varying the excitation wavelength, this excitation‐dependent emission does not constitute true tuning, as the shifted peaks have much weaker intensity than their dominant emission, and this is often undesired in real world applications. We report for the first time the synthesis and photoluminescence properties of carbon dots whose peak fluorescence emission wavelengths are tunable across the entire visible spectrum by simple adjustment of the reagents and synthesis conditions, and these carbon dots are excited by white light. Detailed material characterization has revealed that this tunable emission results from changes in the carbon dots’ chemical composition, dictated by dehydrogenation reactions occurring during carbonization. These significantly alter the nucleation and growth process, resulting in dots with either more oxygen‐containing or nitrogen‐containing groups that ultimately determine their photoluminescence properties, which is in stark contrast to previous observations of carbon dot excitation‐dependent fluorescence. This new ability to synthesize broadband excitable carbon dots with tunable peak emissions opens up many new possibilities, particularly in multimodal sensing, in which multiple analytes and processes could be monitored simultaneously by associating a particular carbon dot emission wavelength to a specific chemical process without the need for tuning the excitation source.     

Field emission properties of N-doped capped single-walled carbon nanotubes: a first-principles density-functional study

The geometrical structures and field emission properties of pristine and N-doped capped (5,5) single-walled carbon nanotubes have been investigated using first-principles density-functional theory. The structures of N-doped carbon nanotubes are stable under field emission conditions. The calculated work function of N-doped carbon nanotube decreases drastically when compared with pristine carbon nanotube, which means the enhancement of field emission properties. The ionization potentials of N-doped carbon nanotubes are also reduced significantly. The authors analyze the field emission mechanism in terms of energy gap between the lowest unoccupied molecular orbital and the highest occupied molecular orbital, Mulliken charge population, and local density of states. Due to the doping of nitrogen atom, the local density of states at the Fermi level increases dramatically and donor states can be observed above the Fermi level. The authors' results suggest that the field emission properties of carbon nanotubes can be enhanced by the doping of nitrogen atom, which are consistent with the experimental results.     

Emission mechanism of polyatomic ions Cs2Cl+ and Cs2BO2(+) in thermal ionization mass spectrometry with various carbon materials

The emission behavior of polyatomic ions Cs(2)Cl(+) and Cs(2)BO(2)(+) in the presence of various carbon materials (Graphite, Carbon, SWNTs, and Fullerenes) in the ionization source of thermal ionization mass spectrometry (TIMS) has been investigated. The emission capacity of various carbon materials are remarkably different as evidenced by the obvious discrepancy in signal intensity of polyatomic ions and accuracy/precision of boron and chlorine isotopic composition determined using Cs(2)Cl(+)-graphite-PTIMS/Cs(2)BO(2)(+)-graphite-PTIMS methods. Combined with morphology and microstructure properties of four selected carbon materials, it could be concluded that the emission behavior of the polyatomic ions strongly depends on the microstructure of the carbon materials used. A surface-induced collision mechanism for formation of such kinds of polyatomic ions in the ionization source of TIMS has been proposed based on the optimized configuration of Cs(2)BO(2)(+) and Cs(2)Cl(+) ions in the gas phase using a molecular dynamics method. The combination of the geometry of the selected carbon materials with the configuration of two polyatomic ions explains the structure effect of carbon materials on the emission behavior of polyatomic ions, where graphite samples with perfect parallels and equidistant layers ensure the capacity of emission to the maximum extent, and fullerenes worsen the emission of polyatomic ions by blocking their pathway.     

Carbon-related matrix effects in inductively coupled plasma atomic emission spectrometry

In Inductively Coupled Plasma Atomic Emission Spectrometry (ICP-AES), it has been observed that the emission intensity of some atomic lines is enhanced or depressed by the presence of carbon in the matrix. The goal of this work was to investigate the origin and magnitude of the carbon-related matrix effects in ICP-AES. To this end, the influence of the carbon concentration and source (i.e. glycerol, citric acid and potassium hydrogen phthalate), the experimental conditions and sample introduction system on the aerosol characteristics and transport, plasma excitation conditions and the emission intensity of several atomic and ionic lines of a total of 15 elements has been studied. Results indicate that carbon related matrix effects do not depend on the carbon source and they become more severe when the amount of carbon loaded into the plasma increases, i.e., when using: (i) carbon concentrations higher than 5 g L^− 1; (ii) high sample uptake rates; and (iii) efficient sample introduction systems. Thus, when introducing carbon into the plasma, the emission intensity of atomic lines with excitation energies below 6 eV is depressed (up to 15%) whereas the emission intensity of atomic lines of higher excitation energies (i.e. As and Se) are enhanced (up to 30%). The emission intensity of the ionic lines is not affected by the presence of carbon. The origin of the carbon-related interferences on the emission intensity of atomic lines is related to changes in the line excitation mechanism since the carbon containing solutions show the same aerosol characteristics and transport efficiencies as the corresponding aqueous solutions. Based on the previous findings, a calibration approach for the accurate determination of Se in a Se-enriched yeast certified material (SELM-1) has been proposed.     

Carbon nanotubes with covalently linked porphyrin antennae: photoinduced electron transfer

Single- and multiwalled carbon nanotubes have been covalently functionalized with free-base porphyrin. The quantity of porphyrin linked to the surface was determined from thermogravimetric and UV-vis analysis. A reversible protonation equilibrium between the attached porphyrin and the residual acid groups of the carbon nanotubes has been identified. Steady-state fluorescence emission spectrum of the solutions of porphyrin-linked carbon nanotubes shows that the porphyrins act as energy absorbing and electron transferring antennae, and the carbon nanotubes act as efficient electron acceptors. The porphyrin-linked carbon nanotubes show 95-100% emission quenching, indicating a fast photoinduced electron transfer.     

污泥化学链燃烧过程中氮迁移转化特性研究

在单流化床反应器上探究了污泥化学链燃烧过程中氮迁移转化特性。由于赤铁矿载氧体反应活性低,采用30%水泥对其改性。结果表明,水泥改性可提高污泥热解气化反应速率以及赤铁矿还原反应速率,进而提高污泥碳转化率,但是NO生成率也增加。随着反应温度的升高,污泥的碳转化率和NO生成率均增加。另外,随着水蒸气浓度的增加,碳转化率增加,同时可降低NO生成。在污泥化学链燃烧过程中,NO生成率为0.286%-0.768%,低于污泥空气焚烧氮氧化物排放量。     

The determination of carbon,phosphorus and sulphur in steel and cast iron with a glow-discharge emission source and an atomic fluorimeter as spectral line isolator

The atomic fluorimeter, an instrument using an atomic vapour generated by cathodic sputtering for isolating resonance spectral lines emitted by an emission source, was used for detecting the vacuum ultraviolet emission lines of carbon, phosphorous and sulphur. A glow-discharge lamp was used as emission source. Detection limits of 0.012, 0.004 and 0.002% were obtained for carbon, phosphorus and sulphur respectively in cast iron and steel. A narrow-band interference filter through which the matrix emission was measured directly by a photomultiplier tube, was used in an effort to correct for varying sputtering rates from different kinds of samples. This monitoring channel proved to be efficient for the determination of phosphorus and carbon in high alloy steels, but was not necessary for sulphur since in this case working curves of the different types of steels coincided.     

二氧化碳电还原制草酸研究进展

近年来, 二氧化碳过量排放所引发的全球变暖等气候问题引起了全世界的广泛关注, 碳减排已成为人类社会可持续发展面临的共同挑战. 利用电化学方法将二氧化碳转化为高附加值化学品是实现碳减排和二氧化碳高附加值利用的理想途径之一, 但仍面临能耗高、 二氧化碳转化率低、 产物选择性差和难分离等问题. 本文以电还原二氧化碳制草酸为例, 从反应机理、 催化剂、 电解液、 催化电极及反应器等方面介绍该反应的研究进展, 对当前二氧化碳电还原制草酸存在的关键问题进行了分析, 并对其未来研究方向进行了展望.     

Enantiomeric separations of amino acids with inductively coupled plasma carbon emission detection

A chiral crown ether column with a pH 1.9 perchloric acid buffered aqueous mobile phase is used to separate amino acid enantiomers by high performance liquid chromatography. An inductively coupled plasma atomic emission spectrometer coupled to the chromatographic system is used as a detector by monitoring the carbon atomic emission line at 193.09 nm. Seven underivatized amino acids are separated and detected resulting in an average mass detection limit of 5 ng (2.5 ng carbon). The chiral crown ether column resolves compounds with a primary amino group near the chiral center by forming a complex between the crown ether and an ammonium ion moiety from the sample. The -form amino acid always elutes faster than its antipode. The carbon emission detector provides nearly identical sensitivities and similar detection limits for any compounds with comparable mass percents of carbon. Quantification is performed on unknown ratios of amino acids using an internal standard without the need for a calibration curve. Summing the calculated amounts of and amino acid and comparing to the known mixture quantity results in an average error of 1.0% for the seven amino acids separated.     

First comparative emission assay of single-wall carbon nanotubes--solutions and dispersions

A variety of single-wall carbon nanotube samples were tested in steady-state and time-resolved emission experiments, where it was found that chemical functionalization and different degrees of oxidation affect the emission behavior.     

豆奶粉提取碳点及含碳点荧光纳米纤维的制备

以豆奶粉为碳源, 以有机硅烷为钝化剂, 用水热合成法制备碳点, 采用静电纺丝技术, 以碳点与聚乙烯吡咯烷酮(PVP)共混溶液为纺丝液, 制备了含碳点的纳米纤维. 通过紫外吸收光谱、 荧光吸收光谱和荧光发射光谱表征了碳点性质. 结果显示, 所得碳点纳米纤维直径分布均匀, 形貌良好, 碳点分散溶液在340~540 nm的紫外光激发下发出强青绿色荧光, 荧光发射峰出现在550 nm处, 并且随着激发波长增加有微弱的红移.     

Enhancing the luminescence of carbon dots with a reduction pathway

Blue luminescent reduced state carbon dots were prepared by reducing carbon dots with NaBH(4). The quantum yield of the reduced state carbon dots increased from 2% to 24% and the maximum emission wavelength shifted from 520 to 450 nm. This offers a simple pathway to enhance the luminescence of carbon dots.     

Electron injection from nanostructured carbon electrodes at moderate cathodic potentials

Voltammograms of electrodes based on nanostructured carbon of different morphology (single-wall carbon nanotubes, carbon nanofilaments, columnar structures) are taken in hexamethylphosphortriamide solutions. For all listed electrodes, direct experimental proof of the electron injection to the electrolyte solution at moderate cathodic potentials is obtained. It is found that this phenomenon is associated with the existence of atomically sharp spots at the electrode surface, which operate as local cathodes for the electron emission. It is shown that the current-voltage characteristics for the electron injection to the electrolyte solution differ from those for the field electron emission current at the electrode/vacuum interface.     

溶液法制备的碳纳米管薄膜的结构分析与场致电子发射机理研究

结合紫外光电子能谱和拉曼光谱对溶液法制备的碳纳米管薄膜的场致电子发射性能进行研究。采用溶液滴涂法制备的碳纳米管薄膜的场致电子发射开启电场约为3.33 MV/m,阈值电场约为5.44 MV/m,以福勒-诺得海姆(Fowler-Nordheim,FN)理论对电子发射进行解释,其发射的增强因子接近103。通过对紫外光电子能谱的分析,发现碳纳米管薄膜的低能量截止端在外加电场作用下逐步降低,表明纳米管薄膜的表面有效势垒在外加电场作用下逐步下降,从而使得碳纳米管薄膜的电子更加容易发射进入真空。结合拉曼光谱和电学特性的研究,发现界面过渡层的接触电阻与碳纳米管薄膜中的非晶碳成分均可以增强场致电子发射。     

“双碳”背景下燃煤电厂制氨与氨利用进展

自2015年12月《巴黎协定》在巴黎气候变化大会上通过以来，世界各国都将碳减排作为政府工作中的重要任务。近年来，随着我国经济的发展和“双碳”目标的提出，有关“碳达峰、碳中和”的研究正在如火如荼地进行，各项碳减排措施正在稳步推进。各个行业，尤其是煤电行业也在抓紧寻找低碳生产和低碳排放的新出路。氨作为重要的工业产品之一，在国民经济中占有重要地位，寻找低碳排放的制氨方法代替传统高碳排放的制氨方式尤为重要。而在燃煤电厂中进行低碳制氨是提升运行灵活性、拓展产品链的重要途径。本文梳理了氨能未来发展的广阔前景和发展优势，重点总结了目前电化学催化制备绿氨技术的研究进展和现有成果，并针对燃煤电厂低碳制氨技术给出了技术路径，为电力行业“双碳”发展提供了新出路。     

Carbon nanofibers grown on sodalime glass at 500°C using thermal chemical vapor deposition

Carbon nanofibers are grown homogeneously on a large area of nickel-deposited sodalime glass substrate by thermal chemical vapor deposition of acetylene at 500°C. The diameters of carbon nanofibers are uniformly distributed in the range between 50 and 60 nm. Most of the carbon nanofibers are curved or bent in shape, but some fractions are twisted. They consist of defective graphitic sheets with a herringbone morphology. The maximum emission current density from the carbon nanofibers is 0.075 mA/cm² at 16 V/μm, which is sufficient for commercializing the carbon-nanofibers-based field emission displays.     

N-DOPED RED EMISSION CARBON DOTS AND DETECTION OF Fe3+

Journal of Structural Chemistry - So far, the fluorescence emission wavelength of carbon dots has been mostly concentrated in the blue-green area, while the number of carbon dots which emit red...     

Electron-withdrawing functional ligand promotes CO2 reduction catalysis in single atom catalyst

Science China Chemistry - Electrochemical carbon dioxide reduction reaction (CO2RR) powered by renewable electricity offers an attractive approach to reduce carbon emission and at the same time...     

Single electron emission from the closed-tips of single-walled carbon nanotubes

The single electron emission behaviors and characteristics from the well-defined quantized energy levels, corresponding to localized electronic states at the dome-structure tips, in single-walled carbon nanotubes (SWNTs) are investigated and illuminated by use of the energy level emission model in combination with the first-principles calculations on the electronic structures. Under the external electric field, the confined electrons are emitted simultaneously from each quantized energy level by virtue of the resonant tunneling effects. With increasing applied voltage, the emission current increases monotonically and exponentially up to the first peak value, and then steps into the increasing and decreasing "sawtoothlike" variations in sequence. The negative differential resistance or conductivity and the maximum current for SWNTs are simulated. The influences of localized electronic states and curvatures of the different closed tips on the single electron emission behaviors of SWNTs are evaluated and discussed. Also a few issues and applications relevant to electron emission of carbon nanotubes are addressed.