product information:
Name: Ti3AlC2/Cr2AlC target thickness 3-5mm
Size: 80*5
Product performance: high purity target
Purity: 99.8%
Application areas: energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc.
Size and process can be customized


Diameter 80mm, thickness 3-5mm

Processing cycle: 2 weeks

产品介绍（Product introduction）

MAX相陶瓷（包括钛碳化硅，Ti3AlC2材料等）是一种备受关注的新型可加工导电陶瓷材料这类陶瓷包含六十多种三元碳化物或氮化物.M代表过渡族前部金属元素; A代表主族元素，主要是第三主族和第四主族的元素; X代表碳或氮元素。其中Ti3SiC2研究最为广泛.Ti3SiC2由美国Drexel大学的Barsoum M教授课题组于1996年用热压法成功合成，并且发现了其优异的性能。由于独特的纳米层状的晶体结构，这类陶瓷材料具有抗氧化，自润滑，室温高断裂韧性和可导电等性能。这类材料可以广泛应用为高温结构材料，电极电刷材料，化学防腐材料和高温发热体等。产品主要用于高温涂层，MXene前驱体，导电自润滑陶瓷，锂离子电池，超级电容器，电化学催化。

MAX phase ceramics (including titanium silicon carbide, Ti3AlC2 materials, etc.) are a new type of processing conductive ceramic materials that have attracted much attention. These ceramics contain more than sixty kinds of ternary carbides or nitrides. M represents the transitional front metal elements. ; A represents the main group element, mainly the elements of the third main group and the fourth main group; X represents a carbon or nitrogen element. Among them, Ti3SiC2 is the most widely studied. Ti3SiC2 was successfully synthesized by hot pressing method in 1996 by Professor Barsoum M of Drexel University in the United States, and its excellent performance was found. Due to the unique nano-layered crystal structure, these ceramic materials have antioxidant, self-lubricating properties, high room temperature fracture toughness and electrical conductivity. Such materials can be widely used as high temperature structural materials, electrode brush materials, chemical anticorrosive materials and high temperature heating elements. The products are mainly used for high temperature coating, MXene precursor, conductive self-lubricating ceramic, lithium ion battery, super capacitor, electrochemical catalysis.

应用领域(Application Fields)

MAX 已经被广泛应用到纳米吸附、生物传感器，离子筛分、催化、锂离子电池、超级电容器、润滑等诸多领域。

MAX have been widely used in nano-adsorption, biosensors, ion sieving, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields.

literature:

Spintronic devices based on ferromagnetic semiconductors, such as non-volatile magnetic memory, have the advantages of low power consumption, fast operation speed, high storage density and strong data retention, and are expected to integrate storage and computing in the future. The fields of information technology and quantum computing have broad application prospects. Two-dimensional magnetic semiconductor materials are essential for improving the performance of spintronic devices. However, most two-dimensional materials, including graphene, do not have intrinsic ferromagnetism and need to be doped and modified to introduce magnetism. Therefore, the search for new two-dimensional magnetic semiconductors with high Curie temperature will provide an important basis for the research of spintronic devices. The research team of Professor Sun Zhimei of Beijing University of Aeronautics and Astronautics has made progress in the research of two-dimensional magnetic semiconductor materials, mainly including the following two aspects. (1) Through first-principles calculations and first-principles molecular dynamics simulation methods, we propose a new way to obtain two-dimensional intrinsic ferromagnetic semiconductors, namely by stripping antiferromagnetic van der Waals semiconductors Obtained a single-layer ferromagnetic semiconductor; and predicted a new type of two-dimensional intrinsic ferromagnetic semiconductor-single-layer CrOCl and CrOBr materials, whose Curie temperature is much higher than the two-dimensional CrI3 and Cr2Ge2Te6 reported in the literature. The calculation results show that this series of two-dimensional materials can be obtained by mechanical peeling method similar to the preparation of graphene, and has good kinetic and thermodynamic stability. This work provides a new idea for the development of a new type of two-dimensional intrinsic ferromagnets. The predicted two-dimensional ferromagnetic CrOCl and CrOBr materials are expected to be applied to non-self-rotating electronic devices. (2) Prediction of semi-metallic ferromagnetic two-dimensional Cr2C crystal and its metal-insulator phase transition induced by surface functionalization. Based on the hybrid functional density theory, we predicted the first semimetal ferromagnetic material in the MXene family, with adjustable electronic properties and magnetic Cr2C, whose charge transport is completely dominated by spin-up electrons, That is, the electron flow through Cr2C will be 100% spin-polarized. The half-metal band gap of Cr2C is as high as 2.85 eV, which ensures that the 100% spin filtering characteristics can be applied in a large bias voltage range. When the surface of Cr2C is saturated with F, OH, H or Cl atomic groups, Cr2C will undergo a transition from metal to insulator, accompanied by a ferromagnetic to antiferromagnetic transition. Therefore, by controlling the type of surface functionalized atomic groups, the energy gap width of the antiferromagnetic state can be well controlled.

注意事项（Notice）

1.量大优惠

Large volume discount

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