Mxene Nanocomposite(Mxene 纳米复合材料)研究综述
Mxene Nanocomposite Mxene 纳米复合材料 - The resulting nanohybrid was introduced into the thermoplastic polyurethane (TPU) matrix via solution mixing followed by the hot-pressing method, affording TPU/PCS-MXene nanocomposite. [1] Secondly, MXene as an electrode material for constructing electrochemical sensors based on MXene nanocomposites, especially metal nanoparticles (MNPs)/MXene, conductive polymers (CPs)/MXene, and carbon materials/MXene nanocomposites, was well discussed. [2] The excellent electromagnetic wave absorption performance of the flexible PVDF/SiCnw/MXene nanocomposites was attributed to the proper impedance matching, enhanced interfacial polarization and high dielectric loss. [3] MXene of good electrical conductivity was used as the immobilized matrix to fabricate Au@CQDs-MXene nanocomposites with the advantages of good electrical conductivity and electrocatalysis. [4] The polymer/MXene nanocomposites have been designed using various techniques such as in situ polymerization, solution method, and other techniques. [5] Ultralight 3D NiCo compound@MXene nanocomposites that inherited hollow polyhedral skeleton and excellent conductive network were fabricated. [6] To meet the needs of practical application, the sandwich-like NiFe2O4@SiO2@MXene nanocomposites were fabricated via multilayered MXene and core-shell NiFe2O4@SiO2 nanoparticles. [7] The high resolution scanning electron microscopy (HR-SEM) was revealed the formation of MXene, and Gr/MXene nanocomposite. [8] First, how the MXene nanocomposite as an electrode modifier affects the sensing performance of the electrochemical biosensors based on enzymes, aptamer/DNA, and immunoassays is well described. [9] The PANI/Pd/MXene nanocomposite was prepared using a one-pot electrochemical co-deposition technique with a pre-anodized screen-printed electrode (SPE) under acidic electrolyte solution containing Ti3C2Tx, aniline, and palladium chloride as precursors. [10] The feasible 1D-2D MnMoO4-MXene nanocomposite-based biosensor effectively detected hydroquinone and catechol in hazardous water pollutants using the differential pulse voltammetric technique with recovery values. [11] Herein, a self-powered motion sensor (SPMS) based on PVDF-TrFE/MXene nanocomposite is newly presented for real-time human motion monitoring. [12] The novel Co3O4@MXene nanocomposites (CMNs) were fabricated by a facile, green and highly tunable strategy without using any chemical modifiers. [13] Electrostatic self-assembled NiFe2O4/MXene nanocomposites exhibit excellent electromagnetic wave absorption performance based on the synergistic effect of bifillers. [14] PdPtBP MNPs/MXene nanocomposites, the novel signal amplification labels, were successfully synthesized using MXenes with the large surface area and the quaternary PdPtBP MNPs nanozymes with outstanding peroxidase-like catalytic activity. [15] Herein, positively-charged black phosphorus (BP) nanoflakes were first prepared by electrochemical exfoliation method and electrostatically assembled with negatively-charged MXene nanosheets, forming heterostructured BP–MXene nanocomposites. [16] Graphical abstract Schematic representation of a novel platinum particles/polyaniline/MXene nanocomposite (Pt/PANI/MXene) for screen-printed carbon electrode (SPCE) modification to enhance the specific surface area for immobilization of lactate oxidase (LOx) and use as enzymatic biosensor for lactate determination in milk sample. [17] The as-obtained CsPbBr3/MXene nanocomposites demonstrated increased photocurrent generation in response to visible light and X-ray illumination, attesting to the potential application of these heterostructure nanocomposites for photoelectric detection. [18] Combining the exceptional properties of MXene with the effective nacre-like structure, PVA/MXene nanocomposites can be used as a novel charge storage material, fulfilling the requirements of flexible electronics and energy storage devices. [19] Conclusion: Our new Au/MXene and Au/Fe3O4/MXene nanocomposites could be safer and more suitable than the pure MXene for biomedical applications, especially when targeted PTT is warranted. [20] 2D metal carbides and nitrides — MXenes — are among the most promising materials for supercapacitors, but so far no MXene nanocomposite with simultaneously optimized mechanical properties and capacitance has been reported. [21]通过溶液混合和热压法将所得纳米混合物引入热塑性聚氨酯 (TPU) 基体中,得到 TPU/PCS-MXene 纳米复合材料。 [1] 其次,对 MXene 作为构建基于 MXene 纳米复合材料,特别是金属纳米颗粒 (MNPs)/MXene、导电聚合物 (CPs)/MXene 和碳材料/MXene 纳米复合材料的电化学传感器的电极材料进行了深入讨论。 [2] 柔性 PVDF/SiCnw/MXene 纳米复合材料优异的电磁波吸收性能归因于适当的阻抗匹配、增强的界面极化和高介电损耗。 [3] 以具有良好导电性的MXene为固定基体,制备了具有良好导电性和电催化性能的Au@CQDs-MXene纳米复合材料。 [4] 聚合物/MXene 纳米复合材料是使用各种技术设计的,例如原位聚合、溶液法和其他技术。 [5] 制备了继承了中空多面体骨架和优异导电网络的超轻3D NiCo化合物@MXene纳米复合材料。 [6] 为了满足实际应用的需要,通过多层 MXene 和核壳 NiFe2O4@SiO2 纳米颗粒制备了三明治状 NiFe2O4@SiO2@MXene 纳米复合材料。 [7] 高分辨率扫描电子显微镜 (HR-SEM) 揭示了 MXene 和 Gr/MXene 纳米复合材料的形成。 [8] 首先,很好地描述了作为电极改性剂的 MXene 纳米复合材料如何影响基于酶、适体/DNA 和免疫测定的电化学生物传感器的传感性能。 [9] PANI/Pd/MXene 纳米复合材料是在含有 Ti3C2TX、苯胺和氯化钯作为前体的酸性电解质溶液下,使用预阳极化丝网印刷电极 (SPE) 的一锅电化学共沉积技术制备的。 [10] 可行的 1D-2D MnMoO4-MXene 基于纳米复合材料的生物传感器使用具有回收值的差分脉冲伏安技术有效地检测了有害水污染物中的对苯二酚和儿茶酚。 [11] 在此,新提出了一种基于 PVDF-TrFE/MXene 纳米复合材料的自供电运动传感器 (SPMS),用于实时人体运动监测。 [12] 新型 Co3O4@MXene 纳米复合材料 (CMN) 采用简便、绿色和高度可调的策略制造,无需使用任何化学改性剂。 [13] 基于双填料的协同作用,静电自组装 NiFe2O4/MXene 纳米复合材料表现出优异的电磁波吸收性能。 [14] PdPtBP MNPs/MXene纳米复合材料是一种新型的信号放大标记物,利用具有大表面积的MXenes和具有优异类过氧化物酶催化活性的四元PdPtBP MNPs纳米酶成功合成。 [15] 在此,首先通过电化学剥离法制备带正电的黑磷(BP)纳米片,并与带负电的 MXene 纳米片进行静电组装,形成异质结构的 BP-MXene 纳米复合材料。 [16] 图形摘要 用于丝网印刷碳电极 (SPCE) 改性的新型铂颗粒/聚苯胺/MXene 纳米复合材料 (Pt/PANI/MXene) 的示意图,以提高固定乳酸氧化酶 (LOx) 的比表面积并用作酶生物传感器用于牛奶样品中的乳酸测定。 [17] 所获得的 CsPbBr3/MXene 纳米复合材料在可见光和 X 射线照射下表现出增加的光电流产生,证明了这些异质结构纳米复合材料在光电检测中的潜在应用。 [18] PVA/MXene 纳米复合材料将 MXene 的卓越性能与有效的珍珠层状结构相结合,可用作新型电荷存储材料,满足柔性电子和储能设备的要求。 [19] 结论:我们的新型 Au/MXene 和 Au/Fe3O4/MXene 纳米复合材料可能比纯 MXene 更安全、更适用于生物医学应用,尤其是在需要靶向 PTT 时。 [20] 二维金属碳化物和氮化物——MXenes——是最有前途的超级电容器材料之一,但迄今为止还没有报道同时优化机械性能和电容的 MXene 纳米复合材料。 [21]
Ti3c2tx Mxene Nanocomposite Ti3c2tx Mxene 纳米复合材料
In this work, In2O3 nanocubes/Ti3C2Tx MXene nanocomposites were synthesized using In2O3 nanocubes and layered Ti3C2Tx MXene via a facile hydrothermal self-assembly method. [1] In this work, biodegradable poly(lactic acid) (PLA)/Ti3C2Tx MXene nanocomposites were prepared through melt compounding. [2] In this work, biodegradable poly(lactic acid) (PLA)/carbon nanotubes (CNTs)/Ti3C2Tx MXene nanocomposites are prepared via co-coagulation and compression molding techniques. [3]在这项工作中,使用 In2O3 纳米立方体和层状 Ti3C2Tx MXene 通过简便的水热自组装方法合成了 In2O3 纳米立方体/Ti3C2Tx MXene 纳米复合材料。 [1] 在这项工作中,通过熔融复合制备了可生物降解的聚乳酸 (PLA)/Ti3C2Tx MXene 纳米复合材料。 [2] 在这项工作中,可生物降解的聚乳酸 (PLA)/碳纳米管 (CNT)/Ti3C2Tx MXene 纳米复合材料是通过共凝聚和压缩成型技术制备的。 [3]
Ti3c2 Mxene Nanocomposite
The open-aperture Z-scan technology is utilized to study the nonlinear absorption features of the Fe3O4@Ti3C2 MXene nanocomposite from 1 to 2 μm, showing a large modulation depth and a relatively low saturable intensity. [1] SnO2–Ti3C2 MXene nanocomposites with different contents of Ti3C2 (0, 0. [2]利用开孔Z扫描技术研究了Fe3O4@Ti3C2 MXene纳米复合材料在1-2μm的非线性吸收特征,显示出较大的调制深度和较低的可饱和强度。 [1] 不同 Ti3C2 含量的 SnO2–Ti3C2 MXene 纳米复合材料 (0, 0. [2]
mxene nanocomposite membrane Mxene 纳米复合膜
The MXene supernatant containing several layers was treated as aqueous solvent for interfacial polymerization, consequently the prepared MXene nanocomposite membrane could maintain high permeselectivity even under low pressures required for low carbon. [1] In this study, we prepared free standing UHAPNWs/MXene nanocomposite membranes via introducing ultralong hydroxyapatite nanowires (UHAPNWs) with different weight ratios into MXene to explore their potential in bone regeneration. [2]将含有几层的 MXene 上清液作为水性溶剂进行界面聚合,因此制备的 MXene 纳米复合膜即使在低碳所需的低压下也能保持高选择性渗透。 [1] 在这项研究中,我们通过将不同重量比的超长羟基磷灰石纳米线 (UHAPNWs) 引入 MXene 中制备了独立的 UHAPNWs/MXene 纳米复合膜,以探索其在骨再生中的潜力。 [2]