氧化程度对氧化石墨烯a-b轴结构及电学性能的影响

采用改进的Hummers法及超声分散等后续处理制备不同氧化程度的氧化石墨烯样品。用XPS、XRD、AFM、UV-Vis及四探针测试仪对样品官能团变化规律、结构、形貌特征以及电学性能进行表征分析。结果表明,氧化石墨烯在超声波的作用下水相条件下可达单层分散,单层氧化石墨烯厚度约为1.4 nm:成膜过程中,在氢键力的作用下氧化石墨烯片层沿c轴重叠形成层状凝聚体,结构有序度较好;随氧化剂(KMn O4)用量增加,碳层平面上含氧官能团含量持续增加,特别是羟基官能团(C-OH)含量的增加,使a-b轴方向最大底面间距(d100和d110)一直增大,直至KMn O4用量达4.0 g时,部分C-OH水解,导致d100与d110略有减小;碳层平面上含氧官能团尤其是环氧官能团(C-O-C)含量的增加,使样品带隙宽度逐渐增大,导电性能越来越差。     

氧化石墨的谱学表征及分析

采用改进的Hummers法,通过改变氧化剂用量获得不同氧化程度的氧化石墨,用X射线衍射(XRD)、红外光谱(FTIR)和拉曼光谱(Raman)对产物进行结构和谱学特性的表征,并结合数学分析软件对部分红外和拉曼数据进行分峰拟合。结果表明,石墨经氧化后形成了含有C-OH、-COOH和C-O-C等官能团的石墨层间化合物;氧化剂用量较少时,石墨片层插层氧化不完全,产物的结构中仍存在未被氧化的原石墨周期性结构;随着氧化剂用量的增加,氧化石墨产物的XRD图中原石墨(002)衍射峰逐渐消失,结构中含氧官能团的量逐渐增加,产物的亲水性也逐渐增强;通过对红外光谱的拟合发现,氧化石墨样品在3 198 cm^-1附近有一个红外吸收峰,应归属于C-OH中OH的伸缩振动;随着氧化剂用量的增加,所得氧化石墨产物的拉曼光谱中D峰与G峰的强度积分比R(I_D/I_G)逐渐增大,产物结构中sp²平面域的平均尺寸逐渐减小。     

氧化程度对氧化石墨结构与阳离子交换容量的影响

通过改进hummers法制备了不同氧化程度的氧化石墨。采用XRD、FTIR及XPS等对不同氧化程度氧化石墨样品的结构特征、含氧官能团种类与含量及阳离子交换容量进行表征。结果表明,石墨经氧化后结构层上键入羟基(C-OH)、环氧基(C-O-C)和羧基(-COOH)等含氧官能团;随氧化程度的增加,石墨结构逐渐全部转化为氧化石墨结构,C-O-C和-COOH的含量逐渐增大,而C-OH的含量先增大后略有减小,阳离子交换容量也表现为先增大后减小,对应的最大值分别为1.70、3.80和4.50 mmol·g^-1;氧化石墨碳平面上C-OH发生去质子化反应在层间产生H⁺,其他阳离子与之交换进入GO层间域,C-OH的含量是影响氧化石墨阳离子交换容量的主要因素,随C-OH含量的增加,氧化石墨样品的阳离子交换容量增大。     

氧化环境和比例对改性Hummers法制备GO的影响

以鳞片石墨(GR)为原料,采用改性Hummers法液相氧化方法制备氧化石墨,通过超声剥离的方法剥离出片状的氧化石墨烯(GO),探讨了H₂SO₄环境与H₂SO₄+H₃PO₄混酸环境和KMnO₄与GR的比例对GO制备的影响。采用FTIR、UV、TG、XRD、SEM和XPS等分析手段对制备的GO进行分析。结果表明：GO外貌是呈褶皱片状,在片层上主要有C=O、C-OH、-COOH和C-O-C等官能团,以共价键形式存在石墨层间;通过TG与XPS数据分析表明在H₂SO₄ H₃PO₄混酸环境下制备的GO含氧官能团较多,并且(KMnO₄)与鳞片石墨的最佳比例是1:4。     

氧化程度对氧化石墨结构与阳离子交换容量的影响

通过改进hummers法制备了不同氧化程度的氧化石墨。采用XRD、FTIR及XPS等对不同氧化程度氧化石墨样品的结构特征、含氧官能团种类与含量及阳离子交换容量进行表征。结果表明,石墨经氧化后结构层上键入羟基(C-OH)、环氧基(C-O-C)和羧基(-COOH)等含氧官能团;随氧化程度的增加,石墨结构逐渐全部转化为氧化石墨结构,C-O-C和-COOH的含量逐渐增大,而C-OH的含量先增大后略有减小,阳离子交换容量也表现为先增大后减小,对应的最大值分别为1.70、3.80和4.50 mmol·g-1;氧化石墨碳平面上C-OH发生去质子化反应在层间产生H+,其他阳离子与之交换进入GO层间域,C-OH的含量是影响氧化石墨阳离子交换容量的主要因素,随C-OH含量的增加,氧化石墨样品的阳离子交换容量增大。     

石墨烯-氧化钌纳米复合材料的水热法合成及电化学电容性能

通过水热法制备了石墨烯-氧化钌(G-RuO₂)纳米复合材料。对样品进行了X射线衍射(XRD),扫描电子显微镜(SEM),透射电子显微镜(TEM)和能量色散谱(EDS)表征。SEM结果表明氧化钌粒子均匀地分散在石墨烯层片上。TEM结果显示氧化钌纳米粒子的平均粒径约为3 nm。对样品进行了循环伏安和充放电性能测试,结果表明在1 A·g^-1的电流密度下,样品在H₂SO₄(1 mol·L^-1)溶液中具有219.7 F·g^-1的比电容。     

不同氧化程度氧化石墨烯的制备及湿敏性能研究

基于氧化石墨烯具有多种含氧官能团和极大的比表面积,研究了不同氧化程度氧化石墨烯的湿敏性能。采用改进的Hummers法制备不同氧化程度的氧化石墨,经过超声分散制备氧化石墨烯水相分散液后,制成氧化石墨烯薄膜湿敏元件。采用X射线衍射、原子力显微镜、红外光谱、拉曼光谱和X射线光电子能谱对实验样品的结构和谱学特性进行表征。结果表明:石墨经氧化后,底面间距增大为0.9 nm左右;随氧化剂用量的增加,氧化石墨中石墨的衍射峰逐渐消失,石墨相微晶尺寸逐渐减小,O/C原子比逐渐增大,氧化程度逐渐升高;氧化石墨烯在水相分散液中可达单层分散,单层氧化石墨烯厚度约为1.3 nm;氧化石墨烯表面接有-OH、C-O-C、C=O和COOH官能团,且官能团含量随氧化程度的升高而增大;氧化石墨烯薄膜元件在室温下对湿度的响应时间约3 s,灵敏度达99%;在11.3%-93.6%相对湿度范围内,元件的电阻随湿度升高显著减小,较高氧化程度的氧化石墨烯薄膜的电阻对数与相对湿度呈线性变化;氧化程度越高,元件灵敏度越高,响应时间越短。     

自旋转换-氧化石墨烯纳米复合材料的制备及磁性

利用氧化石墨烯（GO）表面具有丰富含氧基团的特点,采用原位生长法将经典的亚铁三氮唑自旋转换（SCO）配位聚合物[Fe（Htrz）₂（trz）]（BF₄）负载到二维材料GO的表面。利用X射线粉末衍射（PXRD）、红外光谱（FTIR）、SEM、TEM、拉曼等手段对自旋转换-氧化石墨烯（SCO-GO）纳米复合材料进行了表征。通过光谱表征发现,复合材料的FTIR和PXRD特征峰为GO和[Fe（Htrz）₂（trz）]（BF₄）特征峰的叠加,初步证明了自旋转换-氧化石墨烯纳米复合材料已成功制备。SEM和TEM分析直观地显示立方体状的[Fe（Htrz）₂（trz）]（BF₄）纳米颗粒均匀地分散在氧化石墨烯表面,且随着原位生长时间的增加,GO表面的[Fe（Htrz）₂（trz）]（BF₄）的负载量增加、尺寸增大。拉曼图谱表明[Fe（Htrz）₂（trz）]（BF₄）负载到GO表面后,氧化石墨烯特征拉曼峰的强度比（ID/IG）增大,说明氧化石墨烯的缺陷密集程度增大,[Fe（Htrz）₂（trz）]（BF₄）纳米颗粒与石墨烯之间的作用力增强。磁性测试表明不同自组装时间（1、6、12 h）的SCO-GO复合材料的T_1/2↑分别为381.1、381.5和382.4 K,T_1/2↓分别为345.9、345.0和344.8 K,其磁滞回线宽度分别为35.2、36.5和37.6 K,这是由于不同自组装时间的SCO-GO复合材料中[Fe（Htrz）2（trz）]（BF4）的负载量和尺寸的差异导致的。DSC分析结果和磁性结果一致,证实了SCO-GO复合材料自旋转变温度向高温区移动。     

石墨烯的氧化还原法制备及结构表征

采用改进的Hummers法对天然鳞片石墨进行氧化处理制备氧化石墨,经超声分散,然后在水合肼的作用下加热还原制备了在水相条件下稳定分散的石墨烯。用红外光谱、拉曼光谱、扫描探针显微镜和ζ电位仪对样品进行了结构、谱学、形貌和ζ电位分析。结果表明,石墨被氧化后形成以C=O、C-OH、-COOH和C-O-C等官能团形式的共价键型石墨层间化合物;还原氧化石墨后形成的石墨烯表面的官能团与石墨的相似;氧化石墨烯和石墨烯在碱性条件下可形成稳定的悬浮液;氧化石墨烯和石墨烯薄片厚度为1.0nm左右。考察并讨论了还原过程中水合肼用量,体系反应温度、反应时间和pH值对石墨烯还原程度和稳定性的影响,水合肼用量和反应时间是影响石墨烯还原程度的主要因素;pH值对石墨烯稳定性影响较大。     

长链烷胺及手性钛的螯合物Ti[(OC2H4)3N][OCH(CH3)2]在层状V2O5中的插层行为

用一种简便快速方法合成了一系列长链有机胺插层V₂O₅化合物. 用粉末X射线衍射(XRD)、红外光谱(FT-IR)、漫反射紫外-可见光谱(DR UV-VIS)等手段对插层产品的结构进行了表征. 除了正十六胺插层V₂O₅产品外, 其它长链烷胺插层V₂O₅产品的层间距d₀₀₁与长链烷胺碳数n之间具有良好的线性关系: d₀₀₁＝0.160n_C＋0.731 nm. 正十六胺与V₂O₅反应后生成两个插层相, 一个相的层间距d₀₀₁为4.01 nm, 另一相的d₀₀₁为3.20 nm. 此外, 研究了手性钛的螯合物Ti[(OC₂H₄)₃N][OCH(CH₃)₂] (记为TEAIP)在V₂O₅层间的插层行为, 得到相应的插层产品.     

Preparing graphene oxide–copper composite material from spent lithium ion batteries and catalytic performance analysis

The wide use of lithium ion batteries (LIBs) has created much waste, which has become a global issue. It is vital to recycle waste LIBs considering their environmental risks and resource characteristics. Anode graphite from spent LIBs still possess a complete layer structure and contain some oxygen-containing groups between layers, which can be reused to prepare high value-added products. Given the intrinsic defect structure of anode graphite, copper foils in LIB anode electrodes, and excellent properties of graphene, graphene oxide–copper composite material was prepared in this work. Anode graphite was firstly purified to remove organic impurities by calcination and remove lithium. Purified graphite was used to prepare graphene oxide–copper composite material after oxidation to graphite oxide, ultrasonic exfoliation to graphene oxide (GO), and Cu²⁺ adsorption. Compared with natural graphite, preparing graphite oxide using anode graphite consumed 40% less concentrated H₂SO₄ and 28.6% less KMnO₄. Cu²⁺ was well adsorbed by 1.0 mg L^?1 stable GO suspension at pH 5.3 for 120 min. Graphene oxide–copper composite material could be successfully obtained after 6 h absorption, 3 h bonding between GO and Cu²⁺ with 3/100 of GO/CuSO₄ mass ratio. Compared to CuO, graphene oxide–copper composite material had better catalytic photodegradation performance on methylene blue, and the electric field further improved the photodegradation efficiency of the composite material.     

Posteffects of photoreduction of graphene oxide films

The dark process (posteffect) of increasing the electrical conductivity and spectral absorption in the graphene oxide (GO) film after its preliminary UV irradiation has been studied. The posteffect is due to the conformational relaxation of the structure (flattening) of GO nanosheets after the UV-induced dissociation of oxygen-containing groups. At room temperature, the relaxation time is τ ≈ 300 h and the activation energy in the range of 20–70°C is E _a ≈ 0.6 eV.     

Mass transfer kinetics of graphene oxide prepared by chemical oxidation intercalationg assisted ultrasonic field

The key step of the control reaction for the preparation of graphene oxide (GO) by chemical oxidation of KMnO₄/ concentrated H₂SO₄ oxidation system is the intercalation mass transfer process of oxidizer in graphite. Ultrasonic field can promote the intercalation mass transfer process, but the mass transfer kinetics remains unclear. In this paper, the kinetic model of mass transfer coefficient of graphene oxide sheet intercalated by Mn₂O₇ oxidizer in ultrasonic field was established. The Mn₂O₇ intercalation process after the intervention of the ultrasonic was simulated by COMSOL Multiphysics 5.5 simulation software. The results show that the ultrasonic field makes the Mn₂O₇ solution inside and outside the graphite layer turbulent, and the ultrasonic intervening time has little influence on the concentration distribution and diffusion rate of the solution outside the graphite layer, while it has great influence on the concentration distribution and little influence on the diffusion rate change inside the graphite layer. These results contribute to the improvement of the mass transfer theory for the preparation of GO by ultrasonic assisted chemical oxidation.     

水热合成部分还原氧化石墨烯-K2Mn4O8超级电容器纳米复合材料

通过控制水热反应温度以及氧化石墨烯(GO)与高锰酸钾的填料比, 合成了两组部分还原的GO-K₂Mn₄O₈纳米复合材料. X射线衍射(XRD)分析说明水热过程中合成了α-MnO₂和一种新的晶相K₂Mn₄O₈.通过X射线光电子能谱(XPS)分析了水热反应前后氧化石墨的含氧官能团的变化. 扫描电子显微镜(SEM)显示样品由片状还原的氧化石墨烯构成, 其表面附有许多小的纳米颗粒, 这种结构有利于储能时电子的传递. 通过这两组复合材料的结构分析, 更好地理解了材料的电化学性能的变化. 利用循环伏安法和恒流充放电测试比较了材料的电容性能. 用1 mol·L^-1的硫酸钠做电解液, 电位范围是0-1 V, 在1 A·g^-1的电流密度下, 测得的样品最佳比电容达到251 F·g^-1, 能量密度为32 Wh·kg^-1, 功率密度为18.2 kW·kg^-1. 并且在5 A·g^-1的电流密度下循环1000次后样品的比电容仍维持在初始比电容的88%.     

Thorium adsorption on graphene oxide nanoribbons/manganese dioxide composite material

A functional graphene oxide nanoribbons/manganese dioxide composite material (MnO₂-GONRs) was synthesized by hydrothermal method using graphene oxide nanoribbons (GONRs) as raw material which were formed by longitudinal unzipping of multi-walled carbon nanotubes with KMnO₄ and H₂SO₄. The microstructure of MnO₂-GONRs was characterized by SEM and FT-IR. The various factors affecting the adsorption of Th(IV) in aqueous solution such as pH, solid–liquid ratio, contact time, initial concentration and temperature were investigated by batch static adsorption experiments, and the adsorption mechanism is also discussed. The results showed that MnO₂-GONRs had a good adsorption effect on Th(IV) with a maximum adsorption of 166.11 mg/g.

     

Effect of potassium permanganate on morphological,structural and electro-optical properties of graphene oxide thin films

This work investigated the effect of Potassium Permanganate (KMnO₄) on graphene oxide (GO) properties, especially on electrical properties. The GO thin films were deposited on a glass substrate using drop casting technique and were analysed by using various type of spectroscopy (e.g. Scanning Electron Microscopy (SEM), Ultra- Violet Visible (UV–VIS), Fourier Transform Infrared (FTIR), X-Ray Diffraction (XRD), optical band gap, Raman Spectroscopy). Furthermore, the electrical experiments were carried out by using current–voltage (I-V) characteristic. The GO thin film with 4.5 g of KMnO₄ resulted in higher conductivity which is 3.11 × 10^?4 S/cm while GO with 2.5 g and 3.5 g of KMnO₄ achieve 2.47 × 10^?9 S/cm and 1.07 × 10^?7 S/cm, respectively. This further affects the morphological (SEM), optical (band gap, UV–Vis, FTIR, and Raman), and crystalline structural (XRD) properties of the GO thin films. The morphological, elemental, optical, and structural data confirmed that the properties of GO is affected by different amount of KMnO₄ oxidizing agent, which revealed that GO can potentially be implemented for electrical and electronic devices.     

A high-capacity graphene nanosheet material with capacitive characteristics for the anode of lithium-ion batteries

Graphene nanosheets are prepared from H₂ thermal reduction of graphite oxide at 300 °C. The graphite oxide interlayer has readily been expanded through chemical oxidation of meso-carbon micro-beads graphite raw material. After H₂ reduction, the carbon/oxygen ratio of graphene is increased from that of graphite oxide due to the removal of oxygen-containing functional groups as it is demonstrated from IR spectra. The d-spacing of resulting graphene nanosheets is increased to 0.37 nm, which facilitates lithium intercalation. Such synthesized graphene nanosheet material as anode of lithium-ion battery has exhibited high reversible discharge capacity of 1,540 mAh g⁻¹ at a current density of 50 mA g⁻¹, and the coulumbic efficiency was 97% over 50 cycles. The discharge curve of the anode material shows a continuously increased voltage profile, which is a characteristic of a capacitive material.