介孔碳/石墨烯复合材料的制备及其醌类改性电容性能

首先利用硬模板法制备出介孔碳/石墨烯复合材料,然后向复合材料中引入具有赝电容活性的醌类分子进一步增大材料的电容性能。研究结果表明,负载30%(w/w)叔丁基氢醌的介孔碳/石墨烯复合材料具有最佳的电容性能,在电流密度为0.5 A·g~(-1)时,比电容值为355 F·g~(-1);当电流密度高达30 A·g~(-1)时,其比电容值高达226 F·g~(-1),比电容保持率为64%,表现出良好的速率特性。     

中空分级结构Fe3O4@C/rGO复合材料的合成及其储锂性能

以氧化石墨烯(GO)为基底,Fe(NO_3)_3·9H_2O、异丙醇、甘油为原料,通过溶剂热法和后续热处理过程2步合成了Fe_3O_4@C/rGO复合材料,实现了碳包覆的Fe_3O_4纳米粒子自组装形成的分级结构空心球在氧化石墨烯片上的原位生长。采用X射线衍射(XRD)、扫描电镜(SEM)、透射电镜(TEM)和恒流充放电等手段分析了材料的物理化学性能与储锂性能。结果表明,该复合材料在5.0 A·g~(-1)的电流密度下,仍有437.7 mAh·g~(-1)的可逆容量,在1.0 A·g~(-1)下循环200圈后还有587.3 mAh·g~(-1)的放电比容量。这主要归因于还原态氧化石墨烯(rGO)对碳包覆Fe_3O_4分级空心球整体结构稳定性和导电性的提高。     

聚苯胺-还原氧化石墨烯复合材料的比电容及超级电容性能（英文）

通过同步还原聚苯胺(PANI)-氧化石墨烯(GO)复合物制备得到了聚苯胺-还原氧化石墨烯(PANI-rGO)。由于复合材料中PANI提供了氧化还原反应的电荷,使得PANI-rGO复合材料具有较大的比电容。通过扫描电子显微镜(SEM),紫外-可见光谱和热重量分析法(TGA)对复合物进行了结构和形态的分析。复合材料的形态呈薄片状,聚苯胺是均匀地包裹在氧化石墨烯上的。当电流密度为20 A·g~(-1)时,PANI-rGO复合材料的比电容可高达1069 F·g~(-1)(1.71 F·cm~(-2)),是PANI-GO复合材料的五倍,这是因为复合材料中还原氧化化石墨烯的大比表面和高电导性所引起的。     

GO/ZIF-67模板制备rGO/NiCo2S4及高性能不对称超级电容器

以氧化石墨烯(GO)为基底,在GO表面原位生长ZIF-67并作为模板,经硝酸镍刻蚀、碳化、水热硫化制得rGO/NiCo_2S_4复合材料。采用X射线衍射(XRD)、扫描电子显微镜(SEM)、X射线光电子能谱(XPS)表征复合材料的结构与形貌。随后将rGO/NiCo_2S_4复合材料制成正极材料,测试其电化学性能,测试结果显示:rGO/NiCo_2S_4-1.5 h电极材料在1 A·g~(-1)的电流密度下,其比电容值高达1 577 F·g~(-1),当电流密度达到10 A·g~(-1)时,倍率性能为86.4%,在10 A·g~(-1)的电流密度下循环2 000次后,电容保持率为76.9%。另外,在6 mol·L-1KOH电解液中,由AC//rGO/NiCo_2S_4-1.5 h组成的不对称电容器在功率密度为723 W·kg~(-1)时,能量密度为33 Wh·kg~(-1);在高功率密度为7 277 W·kg~(-1)时,能量密度仍保持为23 Wh·kg~(-1)。     

石墨烯修饰改性制备锂离子电池LiFePO4/LiNi0.8Co0.15Al0.05O2复合正极材料及其性能

采用两步干混-球磨方法制备了石墨烯掺杂改性的锂离子电池LiFePO_4/LiNi_(0.8)Co_(0.15)Al_(0.05)O_2复合正极材料,实现LiNi_(0.8)Co_(0.15)Al_(0.05)O_2材料的高容量和高安全性。借助X射线衍射(XRD)、扫描电镜(SEM)、透射电镜(TEM)、X射线光电子能谱(XPS)以及电化学测试等表征手段对材料的晶体结构、微观形貌和电化学性能进行了较系统的研究。结果表明,石墨烯的存在实现了Li Fe PO4材料在LiNi_(0.8)Co_(0.15)Al_(0.05)O_2材料表面的完全包覆,形成致密的包覆层,进一步抑制LiNi_(0.8)Co_(0.15)Al_(0.05)O_2与电解液之间的副反应,提高活性材料利用率和循环性能。三者之间构成导电网络,加快电子渗透和传输,提高倍率性能。Li Fe PO4质量分数为20%的Li Fe PO4-Graphene/LiNi_(0.8)Co_(0.15)Al_(0.05)O_2样品具有最佳的容量性能和长循环性能,0.1C时放电容量达到202.5 m Ah·g~(-1),3C时放电容量仍然可保持在160.5 m Ah·g~(-1)。50℃在2.8~4.3 V,0.5C下循环100次后,容量保持率为91.9%,优于LiNi_(0.8)Co_(0.15)Al_(0.05)O_2和LiFePO_4/LiNi_(0.8)Co_(0.15)Al_(0.05)O_2样品的72.9%和82.0%。     

氧化石墨烯/聚苯胺复合材料的制备及电化学电容性能的研究

以对苯二胺为引发剂,用苯胺和氧化石墨烯(GO)为原料,采用化学原位聚合法制备了氧化石墨烯/聚苯胺(GP)复合材料,不添加任何表面活性剂和模板剂。采用傅里叶变换红外(FTIR)光谱、X射线粉末衍射(XRD)、扫描电镜(SEM)和透射电镜(TEM)对复合材料进行了物性表征,并对其电化学性能进行了测试。结果显示,复合材料保持了氧化石墨烯的基本形貌,聚苯胺纤维分布在氧化石墨烯层间及所形成的褶皱上。二者形成的二元纳米复合材料,发挥良好的协同作用,电化学性能得到了改善。当电流密度为0.5A·g-1时,复合材料的比电容可以达到623F·g-1,远大于石墨烯和聚苯胺单体的比电容。     

纳米CuFe_2O_4-rGO复合材料的制备及电化学性能

采用溶剂热法成功制备了纳米CuFe_2O_4-rGO复合材料。通过X射线衍射(XRD)、扫描电子显微镜(SEM)、透射电子显微镜(TEM)和电化学工作站对样品的结构、形貌及电容特性进行表征。结果表明,CuFe_2O_4纳米粒子均匀地分散在石墨烯片层间,其中CuFe_2O_4-20%rGO复合材料具有最优的电化学性能,当电流密度1 A·g~(-1)时,其比电容为1 952.5 F·g~(-1),当电流密度为1 A·g~(-1)时,CuFe_2O_4-20%rGO复合材料经1 000次充放电后的比电容保持率为86.17%。     

基于水凝胶衍生的硅/碳纳米管/石墨烯纳米复合材料及储锂性能

通过氧化石墨烯(GO)和壳聚糖(Cs)之间的氢键以及静电作用形成GO水凝胶,从而将纳米硅颗粒和碳纳米管(CNT)原位包封于其中,再经冷冻干燥及随后的热处理制得三维硅/碳纳米管/石墨烯(Si-CNT@G)纳米复合材料。采用X射线衍射(XRD)、扫描电子显微镜(SEM)和透射电子显微镜(TEM)、热重分析(TGA)等技术对制得样品的物相、结构和微观形貌等进行了表征。结果表明,所得复合材料在CNT纵横交织的石墨烯网络中,均匀地分布着纳米硅颗粒。当作为锂离子电池的负极材料时,在两种碳介质的协同作用下,有效缓冲硅材料在充放电过程中脱/嵌锂引起的体积变化,缩短了锂离子和电子传输的距离,Si-CNT@G复合材料表现出较好的循环稳定性以及倍率性能。在500 m A·g~(-1)的充放电电流密度下,经过200圈循环后,其放电比容量仍高达673.7 m Ah·g~(-1),容量保持率高达97%;即使将充放电电流密度升至2000 m A·g~(-1)时,该复合材料仍保持有566.9 m Ah·g~(-1)的高可逆放电比容量。独特的制备方法和优越的储锂性能,使得Si-CNT@G纳米复合材料成为理想的高性能锂离子电池负极材料的候选.     

碳包覆纳米SnSb合金作为高性能钠离子电池负极材料

采用喷雾热解法合成了碳包覆的SnSb/C合金复合材料,利用X射线粉末衍射仪(XRD)、场发射扫描电子显微镜(FESEM)、透射电子显微镜(TEM)等方法对产物的物相和形貌进行了表征,其中SnSb/C颗粒为10 nm左右的复合材料(10-SnSb/C)作为钠离子电池负极时,表现出优异的循环和倍率性能。首圈放电达到722.1m Ah·g~(-1),首圈库仑效率86.3%,在100、1000、3000 m A·g~(-1)下比容量分别为607.7、645.4、452.2 m Ah·g~(-1),在1000 m A·g~(-1)电流下循环200周后可逆容量达到623 m Ah·g~(-1),容量保持率为95%。SnSb/C复合材料出色的储钠性能源于其完全被碳包裹的纳米结构,该结构可以有效提高活性物质的利用率,促进电子、离子的传导,并且抑制纳米粒子在长循环过程中的粉化和团聚。     

表面活性剂对氧化铝修饰富锂锰基正极材料的影响

采用氧化铝修饰改性富锂锰基正极材料,探讨了表面活性剂在修饰改性中的作用。利用扫描电子显微镜、X射线衍射仪、透射电子显微镜和电化学性能测试等方法对材料结构和电化学性能进行分析。实验结果表明,十二烷基三甲基溴化铵(DTAB)能使Al_2O_3纳米颗粒均匀包覆在富锂锰基正极材料表面,有效增强了复合材料结构的稳定性。在600 mA·g~(-1)电流密度下,该复合材料的初始放电容量为186mAh·g~(-1)。经过500次循环后,其可逆放电比容量仍高于132 mAh·g~(-1),初始容量保持率高达71%。此外,电压衰退也被有效抑制,复合材料表现出优异的综合电化学性能。     

Physicochemical Principles of the Synthesis of Porous Composite Materials through the Hydrothermal Oxidation of Aluminum Powder

The main versions of the synthesis of a new class of porous cermet materials such as Al₂O₃/Al, MO_x/Al₂O₃/Al, and M¹/MO_x/Al₂O₃/Al and ceramic composites on their basis were analyzed. These ceramic composites were prepared through the stage of the hydrothermal oxidation of aluminum powder and were designed for catalytic and adsorption processes. Equations that express the dependence of the apparent density of the resulting composite on the density of the initial powder mixture, on the concentration of the powdered active component, and on the conversion of aluminum are given. It was found that the formal kinetics of aluminum oxidation with water at 100°C can be described by the Kolmogorov-Erofeev equation. The results were compared with data obtained in an autoclave at higher temperatures and steam pressures. The synthesis parameters that affect the total pore volume and the specific surface area of aluminum oxide obtained from aluminum powder were determined. For the case of the transfer of soluble components from an autoclave to a press mold, the molar coefficients of this process were calculated. The texture peculiarities of composites were analyzed. The texture exhibited a polymodal character with developed micropore, mesopore, and ultramacropore structures, which are responsible for the high permeability of granulated composites. Factors affecting the mechanical properties of metal ceramics were studied. The catalysts and products of composite materials were exemplified.     

Mm0.78Mg0.22Ni2.48Mn0.09Al0.23Co0.47储氢合金的表面改性

为了提高AB3型合金Mm_(0.78)Mg_(0.22)Ni_(2.48)Mn_(0.09)Al_(0.23)Co_(0.47)(Mm由82.3%La和17.7%Nd组成)的电化学性能,将石墨烯添加到合金中。通过XRD和SEM可以看出,石墨烯并没有改变合金的相结构,仅是简单地附在合金表面。当加入质量分数为2%的石墨烯时,合金电极的最大放电容量Cmax达到364.9 m Ah·g-1。石墨烯的添加加速了合金表面的电化学反应。     

锂离子电池正极材料LiV3-xAlxO8的水热合成与性能

采用水热法制备了Al掺杂的锂二次电池正极材料LiV3-xAlxO8,并用X射线衍射和扫描电镜对材料的晶体结构和形貌进行了表征.以50 mA·g-1进行恒流充放电测试,结果表明Al掺杂能够明显改善材料的电化学性能.在掺杂改性的LiV3-xAlxO8材料中,LiV2.93Al0.07O8的初始容量最高,达到325 mAh·g-1.当掺杂量为x=0.04时,材料的循环性能最佳.LiV2.96Al0.04O8经20次循环后仍保持179 mAh·g-1的比容量,且充放电效率始终维持在98%左右.     

微波固相剥离法制备功能化石墨烯及其电化学电容性能研究(英文)

通过微波固相剥离氧化石墨制备了功能化石墨烯材料。石墨烯的剥离,是由于微波加热过程中氧化石墨烯片上的官能团分解为CO2和H2O,产生的压力超过了片层间的范德华力。形貌表征显示了石墨烯的有效剥离和纳米孔结构的形成。红外光谱分析结果表明微波剥离的功能化石墨烯仍然有少量的官能团残留。N2等温吸附-脱附测试结果表明样品具有高比表面积(412.9m2·g-1)和大孔容(1.91cm3·g-1)。电化学测试结果表明功能化石墨烯具有良好的电化学电容行为和207.5F·g-1的比电容。     

Preparation of palladium composite membranes by modified electroless plating procedure

A thin palladium composite membrane was produced by modified electroless plating procedure. Compared with the conventional electroless plating procedure, the modified electroless plating procedure consists of the activation of a ceramic substrate by the sol–gel process of a Pd(II)-modified boehmite sol. Additionally, the infiltration of an electroless plating solution to a porous substrate during the deposition of palladium was employed with the filter device to improve adherence of a palladium layer to a substrate. The resulting membrane with a thickness of about 1 μm has a high compactness. The membrane shows a hydrogen selectivity of 20–130 for H₂/N₂, and a hydrogen flux of 1.8–87 m³/m²·h, depending on operation conditions.     

石墨烯/硫酸铅复合材料的制备及其在铅酸电池中的电化学性能

利用简单的浸渍法制备了石墨烯/硫酸铅复合材料,使得硫酸铅可以直接用作铅酸电池负极材料。该复合材料分别以100 mA.g-1、200 mA.g-1和300 mA.g-1电流密度放电时,平均放电比容量分别可达到110、94和69 mAh.g-1,而硫酸铅仅为49、5和0.5 mAh.g-1,显示出复合材料在高倍率充放电下更好的比容量和再接受充电能力。循环伏安测试表明石墨烯的电容效应随扫描速率增大而增强,同时析氢也变得严重,使得复合材料在充放电过程中充电效率比纯硫酸铅低20%。在充放电过程中,石墨烯能够提高硫酸铅1倍以上的放电容量,并将充电电压提高0.1 V。XRD和SEM结果显示硫酸铅均匀分布在石墨烯片层上,没有出现团聚现象。     

Biodegradable Gelatin as Template for the Preparation of Mesoporous Alumina

In this study, we propose a time‐ and energy‐saving method using biodegradable gelatin as a green template and a low‐toxicity inorganic aluminum salt (Al(NO₃)₃·9H₂O) as a low‐cost aluminum source for the preparation of mesoporous alumina (γ‐Al₂O₃). The effects of pH (pH 8.0–10.0), gelatin to aluminum source ratio (0–1.9), and the hydrothermal treatment time (0–72 h) are thoroughly explored. The gelatin can assemble with the aluminum species γ‐AlOOH via hydrogen bonding to prevent the self‐condensation of the γ‐AlOOH during the hydrothermal treatment. Distinctly, the mesoporous γ‐Al₂O₃ was obtained from the calcination of the resulting gelatin–γ‐AlOOH composites. Without gelatin, high‐crystallinity γ‐AlOOH formed after the hydrothermal treatment, which transformed into the nonporous γ‐Al₂O₃ with a small surface area (20 m²/g). Finally, it was found that with a gelatin/aluminum ratio of 0.81, reaction pH value of 8.0, and hydrothermal treatment time of 24 h, high‐surface‐area mesoporous γ‐Al₂O₃ (262 m²/g) with pore diameter of 6.3 nm could be synthesized.     

Excellent Capacitive Performance of a Three‐Dimensional Hierarchical Porous Graphene/Carbon Composite with a Superhigh Surface Area

Three‐dimensional hierarchical porous graphene/carbon composite was successfully synthesized from a solution of graphene oxide and a phenolic resin by using a facile and efficient method. The morphology, structure, and surface property of the composite were investigated intensively by a variety of means such as scanning electron microscopy (SEM), transmission electron microscopy (TEM), N₂ adsorption, Raman spectroscopy, and Fourier transform infrared spectroscopy (FTIR). It is found that graphene serves as a scaffold to form a hierarchical pore texture in the composite, resulting in its superhigh surface area of 2034 m²g^?1, thin macropore wall, and high conductivity (152 S m^?1). As evidenced by electrochemical measurements in both EMImBF₄ ionic liquid and KOH electrolyte, the composite exhibits ideal capacitive behavior, high capacitance, and excellent rate performance due to its unique structure. In EMImBF₄, the composite has a high energy density of up to 50.1 Wh kg^?1 and also possesses quite stable cycling stability at 100 °C, suggesting its promising application in high‐temperature supercapacitors. In KOH electrolyte, the specific capacitance of this composite can reach up to an unprecedented value of 186.5 F g^?1, even at a very high current density of 50 A g^?1, suggesting its prosperous application in high‐power applications.     

脱合金制备纳米多孔双金属氧化物NiMoO_4及其电化学性能

采用快速凝固与脱合金相结合的方法制备纳米多孔Ni-Mo合金,然后退火获得三维双连续纳米多孔NiMoO_4,采用XRD、SEM、TEM对多孔NiMoO_4的成分、形貌和结构进行表征,并通过循环伏安、恒电流充放电等方法测试多孔NiMoO_4电极的电化学性能。结果表明,Ni_5Mo_5Al_(90)和Ni_(2.5)Mo_(2.5)Al_(95)经脱合金和退火均可获得纳米多孔NiMoO_4,Mo元素对脱合金具有钉扎作用,可减小多孔合金的骨架和孔隙尺寸,由Ni_5Mo_5Al_(90)合金获得纳米多孔NiMoO_4表现出更为优异的超电容性能,其在1 A·g~(-1)电流密度比容量达708 F·g~(-1),当电流密度增加20 A·g~(-1),其比容保持率达57.1%。在4 A·g~(-1)电流密度下循环充放电1 000次,其比容保持率达91.2%。     

SnS2/GCP(石墨烯复合粉末)微米复合材料作为锂离子电池负极材料的电化学性能

以石墨烯复合粉末为添加剂,采用一步水热法制备了一种SnS₂/GCP微米复合材料。在所得到的复合材料中,SnS₂纳米片相互缠绕组成多孔球状SnS₂颗粒,石墨烯复合粉末均匀的包裹在球状SnS₂颗粒表面。将所制备的SnS₂/GCP微米复合材料用作锂离子电池负极材料测其电化学性能。结果显示,在0.1 A·g^-1的电流密度下可逆比容量为795.6 mAh·g^-1,循环100次后比容量损失不到1%。相比于SnS₂其比容量和循环稳定性得到了明显改善,主要是由于石墨烯复合粉末的加入,不仅缓解了SnS₂颗粒在充放电过程中的团聚和体积膨胀,而且还提高了SnS₂颗粒的电导率。