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Nano titanium oxide and silicon oxide are used for anti -wrinkle fabric treatment

Nano oxides have many amazing properties and are widely used in the textile fields such as antibacterial, deodorizing, and anti -ultraviolet rays, etc functioned textiles. Similarly, nano oxide configuration has also had a positive impact. Add nano titanium dioxide or nano silicon oxide(sio2 hydrophobic or hydrophilic) to the traditional system, to form nano-oxide anti-wrinkle tidal liquids at high speed, and anti -wrinkle arrangement of fabrics.

 

Nano material is a new type of functional material that has a large surface area, many surface activity centers, and strong adsorption capacity. In recent years, the study of nano  titanium dioxide has been started in China. The addition of nano titanium dioxide effectively improves the anti -wrinkle effect of cotton fabrics, and at the same time greatly improves the strength of the fabric. When the content of nano -titanium dioxide is 0.1g/L, the anti -wrinkle performance and improvement of the fabric will be the best.

 

Real silk fabric has excellent hanging, soft luster, and special silk feeling, especially its good comfort and health effects. However, the silk fabric is easy to wrinkle when washing or wetting. In order to improve the rebound performance of real silk, many studies have been conducted at home and abroad. Studies have shown that nano -silicon oxide has many activity points , and its reaction activity is better than nano -titanium dioxide. On the surface of the experiment, the Malaysid Anid Anid anhydride anti -wrinkles can be used as a catalyst. In addition, the best process conditions for nano -silicon oxide as the anti -wrinkle system are: 2g/(50ml) of the Malay acid anhydride concentration, and the baking temperature of the roasting temperature It is 150C. This is realistic and economic value for improving the grade of textiles.

 

Apply unique function of nano powders to develop safe and efficient nano materials and used in textiles has great market prospects. The promotion and application of such technology is expected to give new economic growth points for textiles, medical and health materials, and health care products.

 

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Chinese Scientists Have Made Important Breakthroughs in The Field of Super-strong Carbon Nanotube Fibers

Carbon nanotubes are considered to be one of the strongest materials discovered by humans, with a Young’s modulus of over 1 TPa and a tensile strength of over 100 GPa (the specific strength is as high as 62.5 GPa/(g/cm3). ), more than 10 times stronger than T1000 carbon fiber. Theoretical calculations show that carbon nanotubes are currently the only material that has the potential to help us realize our dream of a space elevator.

How to maintain the excellent mechanical properties of a single carbon nanotube after assembling is the first problem that must be solved in the preparation of super strong fibers. However, the reported strength of carbon nanotube fibers is only 0.5–8.8 GPa, which is far lower than the theoretical strength of carbon nanotubes (>100 GPa). The main reason is that the carbon nanotubes that form fibers are short in length, and the units overlap each other by van der Waals force, which easily slips each other under the action of tension, and cannot fully utilize the inherent high strength of carbon nanotubes. In addition, structural defects and disordered orientations in carbon nanotubes will lead to the decrease of fiber strength. In contrast, ultra-long carbon nanotubes have lengths of centimeters or even decimeters and have perfect structures, consistent orientations, and mechanical properties close to the theoretical limit, which have great advantages in the preparation of ultra-strong fibers.

With the support of the national key R&D program “Nanotechnology”, Professor Wei Fei’s team of Tsinghua University and Professor Li Xide’s team have made a breakthrough in the field of super-strength carbon nanotube fibers. Preparation of ultralong carbon nanotube bundles for theoretical strength. By adopting the method of in-situ airflow focusing, the research team controllably prepared centimeter-scale continuous ultra-long carbon nanotube bundles with definite composition, perfect structure and parallel arrangement, ingeniously avoiding the above-mentioned limiting factors. By preparing ultralong carbon nanotube bundles containing different numbers of units, quantitatively analyzing the effects of their composition and structure on the mechanical properties of ultralong carbon nanotube bundles, a definite physical/mathematical model was established. A “synchronized relaxation” strategy is proposed to release the initial stress of carbon nanotubes in the tube bundle through nanomanipulation, so that it is in a narrow distribution range, and then the tensile strength of the carbon nanotube bundle can be increased to 80 GPa. The above is close to the tensile strength of a single carbon nanotube. The reported tensile strength of ultralong carbon nanotube bundles is superior to all other fiber materials found so far. This work reveals the bright prospect of ultra-long carbon nanotubes for the manufacture of super-strong fibers, and points out the direction and method for the development of new super-strong fibers.

 

As carbon nanotube suppliers, Hongwu Nanomaterial is providing several specs cnts as follows.

1.Single walled carbon nanotube,SWCNTs, D 2nm, L 1-2um, 91%;

2.Single walled carbon nanotube,SWCNTs, D 2nm, L 5-20um, 91%;

 

3.Multi walled carbon nanotube, MWCNTs, D 10-30nm, L 1-2um,99%;

4.Multi walled carbon nanotube, MWCNTs, D 10-30nm, L 5-20um,99%;

5.Multi walled carbon nanotube, MWCNTs, D 30-60nm, L 1-2um,99%;

6.Multi walled carbon nanotube, MWCNTs, D 30-60nm, L 5-20um,99%;

7.Multi walled carbon nanotube, MWCNTs, D 60-100nm, L 1-2um,99%;

8.Multi walled carbon nanotube, MWCNTs, D 60-100nm, L 5-20um,99%;

  1. functionized cnts(-COOH, -OH, -NH2, Ni plated, graphited)
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Some Functional Materials in Electronic Paste

Electronic paste is made by mixing functional materials with conductive binders or dispersants. It usually has a high concentration of solid particles dispersed in a stable liquid medium for easy coating, spraying, printing, and other operations in the manufacturing process of electronic devices. Its main applications are in printed electronics, solar cells, and nano electronic devices. The following are several main functional materials used for preparing electronic pastes:

 

  1. Metal powder: Metal powder is commonly used as a conductive material in electronic pastes, including silver powder, copper powder,silver copper powder, aluminum powder, etc. They have good conductivity and can be used to prepare conductive components and electrodes.

 

  1. Oxide powder: Oxide powder is commonly used as a dielectric or semiconductor material in electronic paste. For example, ZnO(HW-Z713)powder, TiO2(HW-T681,T685,T689)powder, lithium niobate powder can be used to prepare insulation layers or semiconductor materials for electronic components.

 

  1. Semiconductor nanoparticles: It isa type of material with special electrical and optical properties, often used for specific functional applications in electronic pastes. For example, indium tin oxide (ITOHW-V751) nanoparticles are widely used in the preparation of transparent conductive films.

 

  1. Carbonnano materials powders: Carbon based materials such as graphene powder (HW-C963, C966, C968) and carbon nanotubes have excellent conductivity and mechanical properties, and can be used to prepare high-performance electronic devices.

 

  1. Functional additives: In addition to the main functional materials mentioned above, auxiliary functional additives like surfactants, antioxidantsand rheological modifiers are often added to electronic paste to improve their performance and stability.

Hwnanomaterial supply the materials mentioned above, with reliable and stable product quality and excellent price. Welcome to contact us for further info.

 

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Nano Zirconia: Performance, Applications Potential in Consumer Electronics

Nano Zirconia has excellent performance, wide application fields, and great development potential in the field of consumer electronics.

Nano Zirconia has excellent physical properties such as high strength, high temperature resistance, wear resistance, insulation insulation, and expansion coefficients, as well as outstanding performance for its nano size with excellent chemical properties such as corrosion resistance and high conductivity and high -scale surface area, high processing accuracy, strong oxygen storage capacity. It is widely used in structural devices, oxygen sensors, joints, etc; and in the background of consumer electronics in the development of the next generation of backboards, ceramic materials ( ZrO2, YSZ) have great potential.

  1. The backplane and intelligent wearable devices are expected to usher in the era of zirconia ceramics.

The 5G era requires a faster signal transmission speed and will adopt a spectrum above 3GHz, which has shorter wavelength of its millimeter. Compared with the metal backboard, the ceramic backboard has no interference to the signal. The ceramic material combines the characteristics of the shape of the glass, no signal shielding, and high hardness. Yes, it is very suitable for wearable devices and mobile phone backboards.

Among all ceramic materials, in addition to high -strength, high hardness, acid -alkali -resistant corrosion resistance and high chemical stability, the zirconia ceramics have the characteristics of anti -scratch -resistant, no signal shielding, excellent heat dissipation performance, and good appearance effects. Therefore, it has become a new type of mobile phone body after plastic, metal, and glass. At present, the application of zirconia ceramics in mobile phones is mainly two parts: backboard and fingerprint recognition cover.

With the well -known domestic mobile phone manufacturers Huawei and Xiaomi  launching zirconia ceramic backplane phones, the market heat has gradually increased, which has opened the curtain of oxidation and infiltration of mobile phone backplane materials.

  1. Advanced aging and consumption upgrades will increase the penetration rate of oxidation dentures and the market space is broad.

Due to its good biological performance, aesthetics and stability, zirconia ceramic materials are widely used in the field of dental repair. With the intensification of global aging and the improvement of living standards and the attention of the whitening of teeth, the global denture market scale has continued to expand. The penetration rate of oxidation ceramics in the denture materials is expected to further increase, and the market space in the field of domestic oxidation in the field of righteousness will continue to grow.