Mxene Film(Mxene薄膜)研究综述
Mxene Film Mxene薄膜 - In this work, the static contact angles of MXene films were studied using water, glycerol, and diiodomethane. [1] Changes in both mechanical and electrical properties of the MXene film are utilized in the detection of the VOCs. [2] This review focuses on MXene films, an important form of MXene-based materials for practical applications. [3] For applications in portable electronics and miniaturized energy storage devices, MXene films derived from MXene inks can be provided as promising electrodes for thin film supercapacitors. [4] A smart light-responsive actuator with a double control switch is fabricated using a reversible two-way shape memory PTU/MXene film. [5] In this work, we develop a flexible and free-standing MoSe2/MXene film with sandwich structure as an anode for SICs and LICs. [6] The laminar MXene/CNT film possesses much higher strength, elongation and specific capacitance than MXene film due to the engineered porosity, good interaction between MXene flakes and CNTs, and proper CNTs’ distribution. [7] Herein, a flexible, hydrophobic, mechanically robust and electromagnetic-interference (EMI) shielding PTFE/MXene/PI soft ETA is constructed through a very simple and fast “cutting and sticking” method by taping PTFE and PI tapes onto the surface of MXene film. [8] Mechanical and electrical properties of the MXene film are detected simultaneously by the QCM with appropriate sizes of sensing film and electrodes. [9] Such piezoelectric PVDF-TrFE/MXene films are capable of sensing body motion for healthcare. [10] —MSL Densification of MXene films to remove voids results in high-performance films. [11] However, the MXene film with extremely high electromagnetic interference shielding effectiveness cannot be extensively applied to the aerospace engineering because of its high density and low mechanical properties. [12] By laminating a thin polymer film onto a solution-processed MXene layer to protect the MXene film from harsh environmental conditions, we present transparent and flexible MXene electronic devices. [13] Correction for ‘Dynamic response study of Ti3C2-MXene films to shockwave and impact forces’ by Shreyas Srivatsa et al. [14] Then the MXene film is packaged successfully into a commercial earphone and shows an excellent performance at high frequencies, which is very suitable for human audio equipment. [15] MXene films with different work functions are studied as electron and hole collection buffer materials for non-fullerene organic solar cells (OSCs) with poly[(2,6-(4,8-bis(5-(2-ethylhexyl)thiophen-2-yl)-benzo[1,2-b:4,5-b′]dithiophene))-alt-(5,5-(1′,3′-di-2-thienyl-5′,7′-bis(2-ethylhexyl)benzo[1′,2′-c:4′,5′-c′]dithiophene-4,8-dione))] (PBDB-T) and 3,9-bis(2-methylene-(3-(1,1-dicyanomethylene)-indanone))-5,5,11,11-tetrakis(4-hexylphenyl)-dithieno[2,3-d:2′,3′-d′]-s-indaceno[1,2-b:5,6-b′]dithiophene (ITIC) as the active materials. [16] MXenes: oxidation pathways of Ti 3 C 2 T x nanosheetsThe storage and dispersion of MXene films in media influence their oxidation behavior. [17] ” CNFs and Ti3C2Tx colloidal dispersions with different weight ratios can be made into freestanding hybrid films that have both high electrical conductivity and excellent mechanical strength; their layered structure is similar to that of MXene films. [18] The space reduction can be attributed to the moisture loss and de-functionalization (-OH) occurring within the MXene film at elevated temperatures. [19]在这项工作中,使用水、甘油和二碘甲烷研究了 MXene 薄膜的静态接触角。 [1] MXene 薄膜的机械和电气性能的变化用于检测 VOC。 [2] 本综述重点介绍 MXene 薄膜,这是一种用于实际应用的 MXene 基材料的重要形式。 [3] 对于便携式电子产品和小型化储能设备的应用,源自 MXene 墨水的 MXene 薄膜可以用作薄膜超级电容器的有前途的电极。 [4] 使用可逆双向形状记忆 PTU/MXene 薄膜制造具有双控制开关的智能光响应致动器。 [5] 在这项工作中,我们开发了一种具有夹层结构的灵活且独立的 MoSe2/MXene 薄膜作为 SIC 和 LIC 的阳极。 [6] 由于设计的孔隙率、MXene 薄片和 CNT 之间的良好相互作用以及适当的 CNT 分布,层状 MXene/CNT 薄膜比 MXene 薄膜具有更高的强度、伸长率和比电容。 [7] 在此,通过将 PTFE 和 PI 胶带粘贴到 MXene 薄膜表面上,通过非常简单且快速的“切割和粘贴”方法构建了一种柔性、疏水、机械坚固和电磁干扰 (EMI) 屏蔽 PTFE/MXene/PI 软 ETA . [8] MXene 薄膜的机械和电学特性由具有适当尺寸的传感薄膜和电极的 QCM 同时检测。 [9] 这种压电 PVDF-TrFE/MXene 薄膜能够感应身体运动以用于医疗保健。 [10] — MSL 对 MXene 薄膜进行致密化以去除空隙,从而获得高性能薄膜。 [11] 然而,具有极高电磁干扰屏蔽效果的MXene薄膜由于其高密度和低机械性能而无法广泛应用于航空航天工程。 [12] 通过将聚合物薄膜层压到溶液处理的 MXene 层上以保护 MXene 薄膜免受恶劣环境条件的影响,我们展示了透明且灵活的 MXene 电子设备。 [13] Shreyas Srivatsa 等人对“Ti3C2-MXene 薄膜对冲击波和冲击力的动态响应研究”的修正。 [14] 然后将MXene薄膜成功封装到商用耳机中,并在高频表现出优异的表现,非常适合人类的音频设备。 [15] 研究了具有不同功函数的 MXene 薄膜作为具有聚[(2,6-(4,8-双(5-(2-乙基己基)))噻吩-的非富勒烯有机太阳能电池 (OSC) 的电子和空穴收集缓冲材料。 2). -yl)-benzo[1,2-b:4,5-b']dithiophene))-alt-(5,5-(1',3'-di-2-thienyl-5',7 '-双(2-乙基己基)苯并[1',2'-c:4',5'-c']dithiophene-4,8-dione))] (PBDB-T) 和 3,9-bis(2 -亚甲基- (3-(1,1-二氰基亚甲基)-茚满酮))-5,5,11,11-四(4-己基苯基)-二噻吩[2,3-d:2',3'-d'] -s- 茚并[1,2-b:5,6-b']二噻吩(ITIC)作为活性材料。 [16] MXenes:Ti 3 C 2 T x 纳米片的氧化途径 MXene 薄膜在介质中的存储和分散会影响它们的氧化行为。 [17] ” 不同重量比的 CNFs 和 Ti3C2Tx 胶体分散体可以制成具有高导电性和优异机械强度的独立式杂化薄膜;它们的层状结构类似于 MXene 薄膜。 [18] 空间减少可归因于高温下 MXene 薄膜内发生的水分损失和去功能化 (-OH)。 [19]
Ti3c2tx Mxene Film Ti3c2tx Mxene 薄膜
Herein, we construct an ultrafine TiO2 confined in 3D freestanding carbon paper by one-step green in-situ oxidation of Ti3C2Tx MXene film with greenhouse gas CO2. [1] Therefore, in this work, we fabricated sandwiched cellulose nanofiber/boron nitride nanosheet/Ti3C2Tx MXene films by using a simple and effective alternating vacuum filtration method, and as a result, the special sandwich structure endows the film with excellent electromagnetic shielding, insulation and TC performance. [2] Inspired by the high stretchability of kirigami patterns, we demonstrate a bottom-up methodology to design highly stretchable and conductive polydimethylsiloxane (PDMS)/Ti3C2Tx MXene films for electromagnetic interference (EMI) shielding and pressure sensing applications by constructing wrinkled MXene patterns on a flexible PDMS substrate to create a hierarchical surface with primary and secondary surface wrinkles. [3] Significantly, the photodetector is capable of sensing infrared light signal up to 980 nm which exceeds the absorption edge of GaAs (874 nm) due to the generation of hot electrons in Ti3C2Tx MXene film. [4] The controllable construction of lightweight, highly conductive, porous and flexible Ti3C2Tx MXene film is crucial in achieving high-performance electromagnetic interference (EMI) shielding and the next generation of high-rate energy storage materials, but it is difficult to produce. [5] In order to fully excavate Ti3C2Tx's electrochemical energy storage capability, a combination of cold pressing and annealing treatment is developed to fabricate free-standing Ti3C2Tx MXene films featuring well-defined film structure, planar macropores, in-plane defects and expanded interlayer spacing. [6] In this study, we demonstrate a facile method to fabricate ultrathin (~10 nm), Ti3C2Tx MXene films by an interfacial assembly technique. [7] In this paper, we propose an integrated photothermal optical sensor (PHOS) using Ti3C2Tx MXene films. [8] Methods Multilayered Ti3C2Tx MXene films were prepared and characterized by XRD and SEM. [9] Flexible and conductive 3D macroporous Ti3C2Tx MXene films were fabricated and tested as MIB cathodes after the incorporation of Mg ions from a Mg2+-containing electrolyte. [10] Dramatically, the heteroatom-controlled Ti3C2Tx MXene films show reve. [11]在此,我们通过使用温室气体 CO2 对 Ti3C2Tx MXene 薄膜进行一步绿色原位氧化,构建了一种限制在 3D 独立式碳纸中的超细 TiO2。 [1] 因此,在这项工作中,我们采用简单有效的交替真空过滤方法制备了夹层纤维素纳米纤维/氮化硼纳米片/Ti3C2Tx MXene薄膜,因此,特殊的夹层结构赋予了薄膜优异的电磁屏蔽、绝缘和TC表现。 [2] 受剪纸图案的高拉伸性启发,我们展示了一种自下而上的方法,通过在柔性 PDMS 上构建起皱的 MXene 图案来设计用于电磁干扰 (EMI) 屏蔽和压力传感应用的高度可拉伸和导电的聚二甲基硅氧烷 (PDMS)/Ti3C2Tx MXene 薄膜基材以创建具有主要和次要表面皱纹的分层表面。 [3] 值得注意的是,由于在 Ti3C2Tx MXene 薄膜中产生热电子,光电探测器能够感应高达 980 nm 的红外光信号,该信号超过了 GaAs 的吸收边缘 (874 nm)。 [4] 轻质、高导电、多孔和柔性的 Ti3C2Tx MXene 薄膜的可控结构对于实现高性能电磁干扰 (EMI) 屏蔽和下一代高速储能材料至关重要,但生产难度大。 [5] 为了充分挖掘Ti3C2Tx的电化学储能能力,开发了冷压和退火处理相结合的方法,制备了具有明确薄膜结构、平面大孔、面内缺陷和扩大层间距的独立式Ti3C2Tx MXene薄膜。 [6] 在这项研究中,我们展示了一种通过界面组装技术制造超薄(~10 nm)Ti3C2Tx MXene 薄膜的简便方法。 [7] 在本文中,我们提出了一种使用 Ti3C2Tx MXene 薄膜的集成光热光学传感器 (PHOS)。 [8] 方法 制备多层 Ti3C2Tx MXene 薄膜,并通过 XRD 和 SEM 对其进行表征。 [9] 在从含 Mg2+ 的电解质中掺入 Mg 离子后,制造并测试了柔性和导电的 3D 大孔 Ti3C2Tx MXene 薄膜作为 MIB 阴极。 [10] 戏剧性地,杂原子控制的 Ti3C2Tx MXene 薄膜显示出惊人的效果。 [11]
X Mxene Film X Mxene 薄膜
Here, we enhanced the stability of Ti 3 C 2 T x MXene films by coating a continuous zeolitic imidazolate framework-8 (ZIF-8) layer. [1] In this study, we conduct systematic annealing of Ti3C2T x MXene films in which we present the 2D MXene flake phase transformation to ordered vacancy superstructure of a bulk three-dimensional (3D) Ti2C and TiC y crystals at 700 °C ⩽ T ⩽ 1000 °C with subsequent transformation to disordered carbon vacancy cubic TiC y at higher temperatures (T > 1000 °C). [2] In situ X-ray diffraction was employed to simultaneously measure dynamic swelling behavior where Ti3C2T x MXene films displayed selective swelling toward ethanol vapor over CO2 gas. [3]在这里,我们通过涂覆连续沸石咪唑酯骨架 8 (ZIF-8) 层来增强 Ti 3 C 2 T x MXene 薄膜的稳定性。 [1] 在这项研究中,我们对 Ti3C2T x MXene 薄膜进行了系统退火,其中我们在 700 °C ⩽ T ⩽ 1000 ° 下将 2D MXene 薄片相转变为块状三维 (3D) Ti2C 和 TiC y 晶体的有序空位超结构C随后在较高温度(T > 1000°C)下转变为无序碳空位立方TiC y 。 [2] 原位 X 射线衍射用于同时测量动态溶胀行为,其中 Ti3C2T x MXene 薄膜显示出相对于 CO2 气体对乙醇蒸气的选择性溶胀。 [3]
Pure Mxene Film 纯Mxene薄膜
Owing to simultaneously achieving two objectives: (i) widening the interlayer space and (ii) providing conductive connections between the loose MXene layers, enabled by the conductive BC@PPy nanospacer, the approach effectively enhances both ion and electron transport within the layered MXene structure, significantly increasing the areal capacitance of the MXene/BC@PPy film electrode to 388 mF cm−2, which is a 10‐fold improvement from the pure MXene film electrode. [1] The electrochemical testing and molecular dynamics simulation demonstrated the consequently widened ions-transport-channels between few-layered MXene sheets can effectively reduce the diffusion barrier of Zn2+ within the MXene/BCF host electrodes compared to pure MXene film electrodes without BCF nanospacer. [2] 1 times and 45 times higher than those of pure MXene films, respectively. [3]由于同时实现了两个目标:(i)扩大层间空间和(ii)在松散的 MXene 层之间提供导电连接,通过导电 BC@PPy 纳米间隔物实现,该方法有效地增强了层状 MXene 结构内的离子和电子传输,将 MXene/BC@PPy 薄膜电极的面积电容显着提高到 388 mF cm-2,是纯 MXene 薄膜电极的 10 倍。 [1] 电化学测试和分子动力学模拟表明,与没有 BCF 纳米间隔物的纯 MXene 薄膜电极相比,少层 MXene 片之间的离子传输通道因此加宽可以有效降低 Zn2+ 在 MXene/BCF 主体电极内的扩散势垒。 [2] 分别是纯 MXene 薄膜的 1 倍和 45 倍。 [3]
Pristine Mxene Film
However, the desirable flexible positive electrodes with volumetric capacitance comparable with pristine MXene film electrode are rare. [1] CNF loading up to 20%, for example, shows a remarkably high mechanical strength of 341 MPa (an order of magnitude higher than pristine MXene films of 29 MPa) while still maintaining a high capacitance of 298 F g-1 and a high conductivity of 295 S cm-1. [2]然而,具有与原始 MXene 薄膜电极相当的体积电容的理想柔性正极很少见。 [1] 例如,高达 20% 的 CNF 负载显示出 341 MPa 的非常高的机械强度(比 29 MPa 的原始 MXene 薄膜高一个数量级),同时仍保持 298 F g-1 的高电容和295 S cm-1。 [2]
Novel Mxene Film 新型 Mxene 薄膜
A novel MXene film sensor technology that can provide real-time and in situ structural health monitoring of composite structures was proposed in this work. [1] A novel MXene film sensor technology which can provide real time and in situ structure health monitoring of composite structures was proposed in this work. [2]在这项工作中,提出了一种新颖的 MXene 薄膜传感器技术,可以提供复合结构的实时和原位结构健康监测。 [1] 在这项工作中,提出了一种新颖的 MXene 薄膜传感器技术,可以提供复合结构的实时和原位结构健康监测。 [2]
Ti3c2 Mxene Film Ti3c2 Mxene 薄膜
Experiments performed at the Advanced Photon Source at Argonne National Laboratory monitored the changes in the structure of a Ti3C2 MXene film on a platinum current collector as a function of static applied potential between 0. [1] A Ti3C2 MXene film can be used as a high-performance electrode material for flexible supercapacitors owing to its high specific capacitance, excellent conductivity, and remarkable flexibility. [2]在阿贡国家实验室的高级光子源进行的实验监测了铂集流体上 Ti3C2 MXene 薄膜结构的变化,作为静态施加电位在 0 之间的函数。 [1] Ti3C2 MXene 薄膜具有高比电容、优异的导电性和卓越的柔韧性,可用作柔性超级电容器的高性能电极材料。 [2]
mxene film electrode Mxene 薄膜电极
Owing to simultaneously achieving two objectives: (i) widening the interlayer space and (ii) providing conductive connections between the loose MXene layers, enabled by the conductive BC@PPy nanospacer, the approach effectively enhances both ion and electron transport within the layered MXene structure, significantly increasing the areal capacitance of the MXene/BC@PPy film electrode to 388 mF cm−2, which is a 10‐fold improvement from the pure MXene film electrode. [1] The electrochemical testing and molecular dynamics simulation demonstrated the consequently widened ions-transport-channels between few-layered MXene sheets can effectively reduce the diffusion barrier of Zn2+ within the MXene/BCF host electrodes compared to pure MXene film electrodes without BCF nanospacer. [2] However, the desirable flexible positive electrodes with volumetric capacitance comparable with pristine MXene film electrode are rare. [3]由于同时实现了两个目标:(i)扩大层间空间和(ii)在松散的 MXene 层之间提供导电连接,通过导电 BC@PPy 纳米间隔物实现,该方法有效地增强了层状 MXene 结构内的离子和电子传输,将 MXene/BC@PPy 薄膜电极的面积电容显着提高到 388 mF cm-2,是纯 MXene 薄膜电极的 10 倍。 [1] 电化学测试和分子动力学模拟表明,与没有 BCF 纳米间隔物的纯 MXene 薄膜电极相比,少层 MXene 片之间的离子传输通道因此加宽可以有效降低 Zn2+ 在 MXene/BCF 主体电极内的扩散势垒。 [2] 然而,具有与原始 MXene 薄膜电极相当的体积电容的理想柔性正极很少见。 [3]
mxene film sensor Mxene 薄膜传感器
A novel MXene film sensor technology that can provide real-time and in situ structural health monitoring of composite structures was proposed in this work. [1] A novel MXene film sensor technology which can provide real time and in situ structure health monitoring of composite structures was proposed in this work. [2]在这项工作中,提出了一种新颖的 MXene 薄膜传感器技术,可以提供复合结构的实时和原位结构健康监测。 [1] 在这项工作中,提出了一种新颖的 MXene 薄膜传感器技术,可以提供复合结构的实时和原位结构健康监测。 [2]