基于花状MoS_(2)/RGO自清洁吸波纺织品的制备

采用水热反应制备花状硫化钼/还原氧化石墨烯复合材料(MoS_(2)/RGO),并将MoS_(2)/RGO复合材料与聚二甲基硅氧烷(PDMS)协同整理到聚多巴胺(PDA)改性棉织物上,制备自清洁吸波棉织物。探讨了MoS_(2)/RGO复合材料用量、PDMS用量、浸渍时间等因素对整理棉织物疏水性能及吸波性能的影响。结果显示,当MoS_(2)/RGO质量分数为1.5%,PDMS质量分数为4.0%,浸渍时间为30 min时,整理棉织物的疏水性能最佳,水滴接触角(WCA)可达到155.2°,在波段8.2~12.4 GHz范围,匹配厚度为3.5 mm下最小反射损耗(RL_(min))值为-42.81 dB,有效吸收带宽(EAB)为2.08 GHz,展现出优异的吸波性能。同时,整理棉织物对常见液滴具有优异的防污性,可实现良好的自清洁吸波效果。

RGO/MoS_2复合光催化材料的制备及其在可见光照射下对RhB的光催化降解性能

为提高二硫化钼(MoS_2)材料的光催化性能,文中利用水热路线,成功制备了RGO/MoS_2复合光催化材料,并分别通过XRD,XPS,SEM,UV-Vis DRS和PL对复合材料进行了物相、组分、形貌和光学特性表征,研究了不同质量分数的RGO(2.5%,5%,7.5%,10%)对光降解活性的影响。实验结果表明,RGO/MoS_2复合材料对罗丹明B(RhB)染料的光降解效率明显高于纯MoS_2纳米花球,其中7.5%(质量分数)RGO负载量获得了最佳的降解效果,5次循环光降解实验进一步表明,RGO/MoS_2复合光催化剂仍能保持90%以上的降解效率。

还原氧化石墨烯/MoS_2与碳纳米管/MoS_2作为润滑油添加剂的摩擦学性能研究

通过水热法成功制备出还原氧化石墨烯/Mo S2(RGO/Mo S2)与碳纳米管/Mo S2(CNTs/Mo S2)纳米复合材料,采用XRD,SEM以及TEM分别对纳米复合材料样品进行了分析和表征,结果表明所制备的复合材料中Mo S2与还原氧化石墨烯、碳纳米管很好地结合在一起。用UMT-2多功能摩擦试验机测试其作为液体石蜡添加剂的摩擦磨损性能,并对其摩擦机理进行了分析。研究发现,与纯的Mo S2相比,一定比例的RGO/Mo S2纳米复合材料作为润滑油添加剂的摩擦系数降低了18%,相对磨损量减少55%;与碳纳米管增强的纳米复合材料相比,RGO/Mo S2纳米复合材料具有更好的摩擦磨损性能。

花瓣状微球MoS_2/石墨烯复合材料的制备及其电化学性能

采用有利于二维层状结构形成的L-半胱氨酸作为硫源,钼酸钠作为钼源,制备聚乙烯基吡咯烷酮(PVP)辅助水热合成花瓣状微球形貌的MoS2/还原氧化石墨烯复合电极材料(PVP-MoS2/RGO).X射线衍射(XRD)及透射电子显微镜(TEM)证实,经过PVP的适量添加,MoS2有序堆垛结构的片层数目明显减少.扫描电子显微镜(SEM)显示,添加适量PVP的MoS2/石墨烯材料具有分散性更好的花瓣状微球形貌.上述的少层有序堆垛结构及复合材料的良好分散性缩短了MoS2中锂离子的嵌入/脱出路径,使其具有更高的容量、循环稳定性和倍率性能.

石墨烯/二硫化钼复合纳米添加剂的制备及摩擦学性能研究

采用水热法制备了两种不同形貌结构的石墨烯/二硫化钼纳米复合物(RGO/MoS_2-1和RGO/MoS_2-2).通过电子显微镜、拉曼光谱、X射线衍射仪和热重分析仪对所制备材料的形貌、成分和晶格结构进行表征;利用SRV-IV微动摩擦磨损试验机考察了RGO/MoS_2-1和RGO/MoS_2-2作为PAO-4添加剂的摩擦学性能.结果显示具有花状结构的RGO/MoS_2-2与RGO/MoS_2-1相比具有更大的层间距,且因其较大的层间距使得RGO/MoS_2-2表现出较好的摩擦学性能. Raman和XPS对润滑机理的表征结果证实了RGO/MoS_2复合纳米添加剂优异的摩擦学性能归因于吸附和摩擦化学反应的协同作用.

石墨烯/二硫化钼/钴复合材料的结构和磁性

介绍了两步水热反应制备石墨烯/二硫化钼/钴(RGO/MoS_2/Co)复合物的方法,在保护气体Ar气中通过800℃退火提高Co的纯度。为了探究RGO/MoS_2/Co复合物在柔性自旋器件方面的应用,利用X射线衍射、透射电镜、拉曼等技术对RGO/MoS_2/Co的结构和形貌进行表征,并结合磁性测试(VSM)探讨其微观结构和磁性行为。结果发现,大小约10~20 nm钴粒子成功嵌入到网状交联的RGO/MoS_2中,复合物在低温和常温下均表现出铁磁性,使其有望应用于设计的柔性自旋器件中。

Ultra-small amorphous MoS2 decorated reduced graphene oxide for supercapacitor application

Amorphous materials have recently gained much attention as electrode materials in supercapacitor application due to the presence of larger amount active sites which can efficiently increase the storage capacity of the materials.Nano engineering is an elegant approach to fully utilize the advantages of the amorphous structure.Moreover,large surface area and high conductivity of reduced graphene oxide(RGO)can efficiently increase the storage capacity of the system.Exploiting this idea,in the present work,we have successfully synthesized amorphous MoS2 of two different sizes on reduced graphene oxide and thoroughly investigated the supercapacitor behavior of the system.The specific capacitance of the composite structures has been found to be largely increased with decreasing size of the amorphous nano particle.The specific capacitance of amorphous MoS2-RGO composite containing nearly 50 nm of MoS2 found to be 270 F/g whereas when the particle size is reduced to 5–7 nm,value of specific capacitance increases to 460 F/g.The large increase in specific capacitance with the tuning of the size of amorphous nano particle has been explained by the presence of a large number of active sulfur edges of ultra-small MoS2 nano structure along with the better charge transport which can effectively increase the storage capacity of the overall system.The retention in the capacitance of the material has been found to be 90%after 5000 cycles.