Mxene Materials(Mxene 材料)研究综述
Mxene Materials Mxene 材料 - Moreover, the obtained results consistently emphasize the TiO2/Ti3C2/g-C3N4 composite would be a unique material for H2 production and broaden applications of MXene materials. [1] Application of MXene materials in perovskite solar cells (PSCs) has attracted considerable attention owing to their supreme electrical conductivity, excellent carrier mobility, adjustable surface functional groups, excellent transparency and superior mechanical properties. [2] In this study, two-dimensional (2D) MXene materials were employed for the adsorptive removal of phosphate and nitrate ions from waters. [3] The morphology, physicochemical structure and surface property of the MXene materials and resulted membranes were observed by XPS, SEM, water contact angle test, AFM, IR and XPS. [4] Here, we report the discovery of MXene materials as superior photothermal supports for metal nanoparticles. [5] Recent important advances of MXene materials in actuators are objectively reviewed and evaluated, and existing issues are discussed. [6] The extensive research has been explored in this novel family of MXene materials from the discovery of Ti 3 C 2 in 2011. [7] MXene materials have drawn extensive scientific interest in catalysis, batteries, purification, and electromagnetic interference shielding fields; however, their anticorrosion performance is rarely. [8] Herein, current research progress in the use of MXene materials for enhancing the performance and longevity of Li–S batteries is reviewed. [9] Despite the growing interest in MXene materials, there are relatively few reports on MXenes. [10] Two-dimensional (2D) MXene materials can immobilize polysulfides via strong chemisorption and physical hinderance. [11] Our results reveal strong optical phase modulation of Nb2C in the infrared region, thus showing the great potential of MXene materials for use in passive photonic devices. [12] This approach not only gives a superb example for the synthesis of other MXene materials in laboratory, but sheds new light for the future mass production of Ti 3 C 2 T x MXene. [13] MXene materials, a young family of two-dimensional transition-metal carbides and nitrides, hold great promise for diverse demanding applications. [14] Although there are only several reports on the application of MXene materials to gas sensors, MXene and its composite materials are expected to become materials that can effectively detect gases at room temperature, especially for the detection of NH3 and VOC gas. [15] Therefore, this work expands the potential of MXene materials and provides a good strategy to address the challenges of 2D energy storage materials. [16] This work opened a new perspective of the MXene materials for anticorrosion application via a layer-by-layer assembly method. [17] However, because of the competitive reactions in aqueous electrolytes, the application of MXene materials in CO2 electroreduction still remains a challenge. [18] Two-dimensional (2D) MXene materials have attracted great attention as advanced energy storage devices. [19] In addition, MXene materials have adjustable interlayer spacing as well as rich functional groups on the bonding end, which provides great potential to enhance the performance of energy devices. [20] It is believed that the proposed study based on the design and integration of MXene materials will provide a general platform for next-generation self-powered electronics. [21] Carbon-based and MXene materials have received increasing attention due to their unique layered structure to accommodate the larger sodium and potassium ions. [22] 26 ps for the first time based on MXene materials. [23] 2D accordion-like MXene materials have been studied a lot as electrode materials for Na/K ion battery for their vast interlamellar spacing, but they suffer from layers’ restacking. [24] Our study broadens the application of Sc2CO2 in gas sensor and provides feasible way to enhance the CO sensibility of MXene materials. [25] This chapter highlights new avenues for more innovative developments of MXene materials in environmental applications. [26] This study paves way for electrocatalytic applications of MXene materials by tuning their surface functional groups. [27] Our work increases understanding of the safe use of MXene materials and points toward their possible use in fields spanning from energy storage systems to medical devices. [28] MXene materials have the advantages of large specific surface areas, abundant active adsorption sites, good hydrophilicity and controllable layer space, and such purely inorganic materials also exhibit excellent radiation resistance and thermal conductivity, thus can be considered as ideal candidates for the sequestration of radioactive element and heavy metal ions. [29] Thus, those MXene materials can be considered as extremely stiff 2D materials. [30] The synthesis process and research concept could also be extended for further application of MXene materials and studies on sodium-ion batteries. [31] MXene materials with efficient electromagnetic (EM) microwave absorber applications are in high demand. [32] A series of MXene materials with high specific surface areas was obtained by HF treatment of MAX materials at 25 °C, 35 °C and 45 °C, named MXene-25, MXene-35 and MXene-45, respectively. [33] Our work reveals the application of MXene materials in the fabrication of NC hydrogels with enhanced mechanical and drug release behaviors. [34] Using the conductivity of MXene materials and the ability of Au@Pt nanoflowers to catalyze the oxidation of H 2 O 2 , a dual-enzyme biosensor was assembled and prepared for sensitive and rapid detection of IMP. [35] Herein, we propose that tailoring appropriate surface functionalization and the intrinsic electrical properties can dramatically enhance the lithium storage capability of Ti3C2Tx (T stands for F, OH, and O) MXene materials. [36]此外,所获得的结果始终强调 TiO2/Ti3C2/g-C3N4 复合材料将是一种独特的制氢材料,并拓宽了 MXene 材料的应用。 [1] MXene材料在钙钛矿太阳能电池(PSCs)中的应用由于其卓越的导电性、优异的载流子迁移率、可调节的表面官能团、优异的透明度和优异的机械性能而引起了广泛关注。 [2] 在这项研究中,二维 (2D) MXene 材料用于吸附去除水中的磷酸盐和硝酸盐离子。 [3] 通过XPS、SEM、水接触角测试、AFM、IR和XPS对MXene材料和所得膜的形貌、物理化学结构和表面性质进行了观察。 [4] 在这里,我们报告了 MXene 材料作为金属纳米粒子的优越光热载体的发现。 [5] 客观地回顾和评估了 MXene 材料在执行器中的最新重要进展,并讨论了存在的问题。 [6] 从 2011 年发现 Ti 3 C 2 开始,对这一新型 MXene 材料家族进行了广泛的研究。 [7] MXene 材料在催化、电池、净化和电磁干扰屏蔽领域引起了广泛的科学兴趣;然而,它们的防腐性能却很少。 [8] 在此,综述了当前使用 MXene 材料提高锂硫电池性能和寿命的研究进展。 [9] 尽管人们对 MXene 材料的兴趣与日俱增,但关于 MXenes 的报道却相对较少。 [10] 二维 (2D) MXene 材料可以通过强化学吸附和物理位阻来固定多硫化物。 [11] 我们的结果揭示了 Nb2C 在红外区域的强光相位调制,从而显示了 MXene 材料在无源光子器件中的巨大潜力。 [12] 这种方法不仅为实验室合成其他 MXene 材料提供了一个极好的例子,而且为 Ti 3 C 2 T x MXene 的未来大规模生产提供了新的思路。 [13] MXene 材料是一个年轻的二维过渡金属碳化物和氮化物家族,在各种苛刻的应用中具有巨大的前景。 [14] 虽然关于将MXene材料应用于气体传感器的报道只有几篇,但MXene及其复合材料有望成为能够在室温下有效检测气体的材料,尤其是对NH3和VOC气体的检测。 [15] 因此,这项工作扩展了 MXene 材料的潜力,并为应对二维储能材料的挑战提供了良好的策略。 [16] 这项工作通过逐层组装方法为 MXene 材料的防腐应用开辟了新的视角。 [17] 然而,由于水性电解质中的竞争反应,MXene 材料在 CO2 电还原中的应用仍然是一个挑战。 [18] 二维 (2D) MXene 材料作为先进的储能器件引起了极大的关注。 [19] 此外,MXene材料具有可调节的层间距以及键合端丰富的官能团,为增强能源器件的性能提供了巨大潜力。 [20] 相信基于 MXene 材料的设计和集成的拟议研究将为下一代自供电电子设备提供通用平台。 [21] 碳基和 MXene 材料因其独特的层状结构可容纳更大的钠离子和钾离子而受到越来越多的关注。 [22] 首次基于 MXene 材料达到 26 ps。 [23] 二维手风琴状 MXene 材料因其巨大的层间距而被大量研究作为钠/钾离子电池的电极材料,但它们会受到层重新堆叠的影响。 [24] 我们的研究拓宽了 Sc2CO2 在气体传感器中的应用,并为提高 MXene 材料的 CO 敏感性提供了可行的途径。 [25] 本章重点介绍了 MXene 材料在环境应用中的更多创新发展的新途径。 [26] 该研究通过调整其表面官能团为 MXene 材料的电催化应用铺平了道路。 [27] 我们的工作增加了对安全使用 MXene 材料的理解,并指出了它们在从储能系统到医疗设备等领域的可能用途。 [28] MXene材料具有比表面积大、活性吸附位点丰富、亲水性好、层间距可控等优点,而且这种纯无机材料还表现出优异的耐辐射性和导热性,可被视为放射性元素封存的理想候选材料。和重金属离子。 [29] 因此,这些 MXene 材料可以被认为是极其坚硬的二维材料。 [30] 合成过程和研究理念也可以延伸到 MXene 材料的进一步应用和钠离子电池的研究。 [31] 具有高效电磁 (EM) 微波吸收器应用的 MXene 材料需求量很大。 [32] 在25°C、35°C和45°C下对MAX材料进行HF处理,得到一系列具有高比表面积的MXene材料,分别命名为MXene-25、MXene-35和MXene-45。 [33] 我们的工作揭示了 MXene 材料在制造具有增强的机械和药物释放行为的 NC 水凝胶中的应用。 [34] 利用MXene材料的导电性和Au@Pt纳米花催化H 2 O 2 氧化的能力,组装并制备了双酶生物传感器,用于灵敏、快速地检测IMP。 [35] 在此,我们建议定制适当的表面功能化和固有的电性能可以显着提高 Ti3C2Tx(T 代表 F、OH 和 O)MXene 材料的锂存储能力。 [36]
2d Mxene Materials 2d Mxene 材料
Exploiting solution based 2D MXene materials can expedite their practical application in PE devices by overcoming the present limitations of conductive inks such as poor conductivity and the high cost of alternative functional inks. [1] The simple fabrication of MXene-GaN-MXene photodetectors spearheaded the way to high performance photodetection by combining the advantages of emerging 2D MXene materials with the conventional III-V materials. [2] This paper reveals a new application of 2D MXene materials as a novel efficient barrier against hydrogen permeation and the subsequent alleviation of hydrogen embrittlement in the steel substrate. [3] In recent years, the novel 2D MXene materials have occupied the forefront due to their superior optical and electronic, as well as mechanical and chemical properties. [4] These findings are based on 2D MXene materials and the resulting 3D host provides a practical approach for achieving stable and safe alkali metal anodes. [5] However, there are few academic reports on the use of 2D MXene materials as memristors. [6] This work presents an example that the catalytic activity of Ti3C2 MXene-supported metals can be promoted by their hydrogen adsorption, which will broaden the application of other 2D MXene materials in catalysis. [7] The findings will open a new perspective for 2D MXene materials’ application as efficient anticorrosion additive. [8]开发基于溶液的 2D MXene 材料可以通过克服导电油墨目前的局限性(例如导电性差和替代功能性油墨的高成本)来加快其在 PE 设备中的实际应用。 [1] MXene-GaN-MXene 光电探测器的简单制造通过将新兴 2D MXene 材料与传统 III-V 材料的优势相结合,率先实现了高性能光电探测。 [2] 本文揭示了 2D MXene 材料的新应用,可作为一种新型的有效阻挡氢渗透的屏障,并随后缓解钢基材中的氢脆。 [3] 近年来,新型二维MXene材料以其优异的光学和电子以及机械和化学性能占据了前沿。 [4] 这些发现基于 2D MXene 材料,由此产生的 3D 主体为实现稳定和安全的碱金属阳极提供了一种实用的方法。 [5] 然而,关于使用 2D MXene 材料作为忆阻器的学术报道很少。 [6] 这项工作提供了一个例子,即 Ti3C2 MXene 负载金属的催化活性可以通过其氢吸附来提高,这将拓宽其他 2D MXene 材料在催化中的应用。 [7] 这些发现将为二维 MXene 材料作为高效防腐添加剂的应用开辟新的前景。 [8]
Dimensional Mxene Materials 三维 Mxene 材料
This work sheds light on the utilization of two-dimensional MXene materials in high-performance optoelectronic devices. [1] This work provides a method to significantly and simultaneously tailor the hydrogen sorption thermodynamics and kinetics of MgH2 by two-dimensional MXene materials. [2] Application of two-dimensional MXene materials in photovoltaics has attracted increasing attention since the first report in 2018 due to their metallic electrical conductivity, high carrier mobility, excellent transparency, tunable work function and superior mechanical property. [3] Two-dimensional MXene materials have been deemed to be potential anode material for sodium ion batteries. [4]这项工作揭示了二维 MXene 材料在高性能光电器件中的应用。 [1] 这项工作提供了一种通过二维 MXene 材料显着并同时调整 MgH2 的氢吸附热力学和动力学的方法。 [2] 自 2018 年首次报道以来,二维 MXene 材料在光伏领域的应用因其金属导电性、高载流子迁移率、优异的透明度、可调节的功函数和优异的机械性能而受到越来越多的关注。 [3] 二维 MXene 材料已被认为是钠离子电池的潜在负极材料。 [4]
New Mxene Materials
These results open up Cr2C to experimental study, including of its predicted emergent magnetic properties, and develop guidelines for synthesizing new MXene materials. [1] At the same time, the introduction of new MXene materials also provides a new idea for the study of new anode materials for magnesium batteries. [2]这些结果为 Cr2C 的实验研究开辟了道路,包括其预测的涌现磁性,并为合成新的 MXene 材料制定了指南。 [1] 同时,新型MXene材料的推出也为镁电池新型负极材料的研究提供了新思路。 [2]