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Nanomaterials for textiles

With the development of science and technology and the improvement of human living standards, people have imcreasing requirements on comfortable and novel health care for clothing. Now people apply nano materials to textiles, and various functional textiles have emerged. Here are a few nano materials for textiles.

1.Nano zinc oxide

The photocatalytic antibacterial mechanism of Zinc Oxide Nanopowder and the antibacterial mechanism of metal ion dissolution have an antibacterial and deodorizing function; the nano zinc oxide has a strong absorption effect on ultraviolet rays in the range of 200-400 nm, and can be used as an ultraviolet shielding agent.

Nano zinc oxide itself is non-toxic and environmentally friendly; compared with antibacterial nano silver, the price is much lower.

Because of these functions and advantages, nano zinc oxide can be used to make functional textiles with antibacterial deodorizing function and UV protection.

2.Nano titanium oxide

Nano TiO2 has the basic properties of nano functional materials, and is used in textiles to have functions such as UV resistance, self-cleaning, air purification, anti-static, anti-infrared, anti-aging, etc.

Nano titanium dioxide is used in the textile slurry. Through the perfect combination with starch, the comprehensive weaving performance of the yarn is improved, the amount of PVA is reduced, the cooking time is short, the slurry cost is reduced, the sizing efficiency is improved, and the PVA pulp is also solved. It is not easy to desizing, environmental pollution and many other problems. Nano-titanium dioxide nano-titanium dioxide is mainly used to replace PVA in the yarn, which acts as a smooth hair, fills the gap and lubricates.

3.Nano silica

Nano-silica powder used in textiles can enhance the adhesion of the slurry to the fiber. The active hydroxyl groups on the surface and the hydrogen bonds on the starch and the hydroxyl groups on the cotton fibers have strong or weak hydrogen bonding, which can effectively improve the pure cotton and polyester. The sizing performance of cotton yarn; nano-silica is more beneficial to the sizing of cellulose fibers; it has the effect of enhancing and grinding and reducing hairiness.

Hydrophobic nano silica can be used to make hydrophobic textiles.

 

4.Nano antimony trioxide

Nano Antimony trioxide is a commonly used inorganic flame retardant and does not have good flame retardancy. However, when it is used together with a halogen flame retardant, it will have a great synergistic effect. Commonly used cerium oxides are antimony trioxide and antimony pentoxide, mainly antimony trioxide, and its flame retardant performance is 3-5 times that of antimony pentoxide. Therefore, it is generally believed that the flame retardant of antimony is antimony trioxide, which can be used for preparing flame retardant textile coatings, non-woven coating coating flame retardant, carpet flame retardant and other fireproof coatings, fire retardant coating flame retardant and the like.

In practical applications, it is often the case that several nano materials are mixed with other auxiliaries in textiles for new and functional textiles.

Nano-textiles are favored by researchers and companies for their superior performance, and the variety is growing. It is believed that these nano materials market for textiles will be increasing. https://www.hwnanomaterial.com/

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Thermal Conductive Filler Alumina Powder

Commonly used thermal conductive materials are:  auminum oxide nanopowder, zinc oxide nanopowder, magnesium oxide nanopowder, aluminum nitride, boron nitride, silicon carbide and so on.

Alumina Al2O3 has the advantages of thermal conductivity and insulation, and can be used as a thermally conductive filler to prepare thermally conductive insulating glue, potting glue and other polymer materials. Compared with other fillers, although the thermal conductivity of alumina is not the best, it can basically meet the basic thermal conductivity requirements. In addition, the price of alumina is relatively low, and the source is relatively wide. It is an economical and suitable filler for high thermal conductivity insulating polymers.

Hongwu Nano can produce white alumina micron powder in batches, with narrow particle size distribution, stable process and high thermal conductivity. According to customer feedback, the thermal conductivity can reach between 3-10W/(m*K) according to different filling amounts.

The particle size of alumina powder used for thermally conductive fillers is 1um, 500nm, 300nm, 200nm. The bulk price is more cost-effective.

Thermally conductive alumina can be widely used in different materials such as silica gel, potting glue, epoxy resin, plastic, rubber thermal conductivity, thermal conductive plastic, silicone grease, heat dissipation ceramics, etc. In practical applications, Al2O3 powder filler can be used alone or mixed with other fillers such as AIN and BN.

In order to improve the dispersibility of the alumina powder, the surface of the alumina can be modified with a silane coupling agent or hexadecyltrimethoxysilane.

If you want to know more about the thermal conductivity of alumina, please feel free to consult online at any time!

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Antibacterial Mechanism and Use of Zinc Oxide Nanoparticles

Nano zinc oxide ZNO is a new type of multifunctional fine inorganic material. Due to the miniaturization of particles, nano zinc oxide powder produces surface effects, small size effects, quantum effects and macro quantum tunneling effects that are not available in bulk materials. It exhibits many special properties, such as non-toxic, non-migrating, fluorescent, piezoelectric, antibacterial and deodorizing, absorbing and scattering ultraviolet rays, etc. Due to the abundant sources of ZnO raw materials and low prices, while zinc is also a mineral element necessary for the human body, nano-ZnO has become one of the hotspots in the research of inorganic antibacterial agents.

Nano-zinc oxide also has many new uses in the field of science and technology, such as manufacturing gas sensors, phosphors, antibacterial materials, ultraviolet shielding materials, varistors, image recording materials, piezoelectric materials, pressure-sensitive materials, varistors, high-efficiency roughness, and magnetism. Materials and plastic films, etc.

There are two antibacterial mechanisms of nano-zinc oxide ZNO:

Photocatalytic antibacterial mechanism. That is, nano-zinc oxide can decompose negatively charged electrons in water and air under the irradiation of sunlight, especially ultraviolet light, while leaving positively charged holes, which can stimulate oxygen change in the air. It is active oxygen, and it oxidizes with a variety of microorganisms, thereby killing the bacteria.

The antibacterial mechanism of metal ion dissolution is that zinc ions will gradually be released. When it comes into contact with the bacteria, it will combine with the active protease in the bacteria to make it inactive, thereby killing the bacteria.

The antibacterial finishing and research on cotton fabrics by nano-zinc oxide and ordinary zinc oxide found that the antibacterial effect of nano-zinc oxide is the result of two antibacterial mechanisms of photocatalysis and metal ion elution. Nano-zinc oxide has antibacterial properties against Staphylococcus aureus Stronger than E. coli, the smaller the size of the nanoparticles, the stronger the photocatalytic effect.

The practical applications of nano-zinc oxide ZNO in antibacterial and anti-ultraviolet functions are summarized as follows:

The field of daily necessities

Applications in apparel, such as sweatshirts, blouses, uniforms, trousers, professional wear, swimwear and children’s wear. It is also used in industry and decoration, such as: advertising cloth, outdoor decoration cloth and so on.

Professional hygiene

For medical use, the antibacterial polyester staple fiber of nano-zinc oxide can be blended with cotton to make hospital bed sheets, surgical gowns, doctor work clothes, patient clothes, etc. For civilian use, it can be used in the food industry and various bedding, furniture cloth, decorative cloth, etc., sterile surgical gowns, sterile masks, sanitary covering materials, etc.

Fields of outdoor work

The anti-ultraviolet properties of nano-zinc oxide make it can be used to produce all kinds of parasols, curtains, transportation tarps and all kinds of tent cloths.

If you need to use nano zinc oxide powder for your application, please contact us.

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Antibacterial Properties of Nano Zinc Oxide Powder

Antibacterial Properties of Nano Zinc Oxide Powder Among the many nano-material antibacterial agents, nano-zinc oxide has a strong inhibitory or killing effect on pathogenic bacteria such as Escherichia coli, Staphylococcus aureus, and Salmonella, and nano-level zinc oxide is a new type of zinc source. With selective toxicity and good biocompatibility, it also has the characteristics of high biological activity, good immunomodulatory ability and high absorption rate, so it has been paid more and more attention by related researchers.

When the particle size is reduced to the nanometer level (20-30nm), the nanoparticle has a higher surface activity and a larger specific surface area, which increases the area of ​​contact and reaction with the bacteria, so the toxicity of the nano-zinc oxide to the bacteria shows To find out a certain particle size dependence, the researchers studied the inhibitory effects of six different sizes of zinc oxide particles on the growth of Staphylococcus aureus, and found that when the particle size of nano-zinc oxide is >100nm (concentration is 6mmol.L-1) ), there is no obvious growth inhibitory effect on Staphylococcus aureus, and when its particle size is less than 30nm, it not only inhibits the growth of the bacteria, but even has a lethal effect on it.

Antibacterial mechanism of nano-zinc oxide
At present, there are many research reports on the antibacterial or sterilization of nano-zinc oxide. The existing literature mainly summarizes its antibacterial or sterilization mechanism into three aspects:

1. Release of free Zn2+;
The metabolic balance of the metal ion ZN2+ is essential for the survival of bacteria. Studies have shown that nano-zinc oxide slowly releases ZN2+ in an aqueous medium, and ZN2+ can penetrate the cell membrane to enter the cell, and while destroying the cell membrane, it reacts with certain groups on the protein to destroy the structure and physiological activity of the bacteria. It enters the enzyme that destroys the electron transfer system in the bacteria and reacts with -SH to achieve the purpose of sterilization, and after killing the bacteria, ZN2+ can be freed from the cell and repeat the above process.

2. The interaction between nanoparticles and the surface of bacteria;
The antibacterial properties of metal oxides can also be attributed to the interaction between nanoparticles and the surface of bacteria, which in turn causes damage to the surface of bacteria.
Researchers studied the effect of nanometer zinc oxide on the growth of Escherichia coli. The results show that when the pH value is 7, the potential of nano-zinc oxide is +24mV. When the surface of Escherichia coli produces a large amount of amide due to the hydrolysis of lipopolysaccharide, the bacterial membrane is negatively charged, and it is produced between the oppositely charged nano-zinc oxide Electrostatic attraction leads to a close association between the two and damages the surface of the bacteria, which in turn leads to the rupture of the bacterial membrane and ultimately the death of the bacteria. When the nano-zinc oxide particles interact with Campylobacter jejuni, the nano-particles can also cause changes in the morphology of the bacteria and leakage of the contents, and induce an increase in the expression of oxidative stress genes in the organism. The above studies have shown that the antibacterial properties of nano-zinc oxide are closely related to the interaction between the particles and the surface of the bacteria.

3. The generation of ROS reactive oxygen free radicals.
Metal oxide particles generate ROS (such as hydrogen peroxide, hydroxyl radicals, oxygen anions and hydroperoxides) in cells are also an important toxicity mechanism. The ROS induced by nanoparticles has been generally considered to be a common form of particle induction. The induced ROS can cause a series of biological reactions, such as damage to the bacterial membrane, which can cause lysis or promote the aggregation of nanoparticles in the bacterial body. Eventually cause the bacteria to die.
Nano-zinc oxide particles have photocatalytic properties, which can produce optical toxicity and cause lethal effects on bacteria under the irradiation of visible light or ultraviolet rays.
The researchers selected Escherichia coli and Bacillus subtilis as the test bacteria, and studied the damage degree of nano-zinc oxide to the two bacteria under light and dark conditions, respectively. It was found that the photocatalytic activity of the light-induced particles caused bacterial membrane breakage and DNA damage. At the same time, it was observed by SEM that the cells were sunken or only degraded bacterial membrane remained due to the leakage of bacterial contents.

Nano-zinc oxide is being widely used in the fields of animal husbandry, textiles, medical treatment, cosmetics and food packaging. The antibacterial effect of nano-zinc oxide is mainly concentrated on bacteria, such as Staphylococcus aureus and Escherichia coli, and shows good in vitro antibacterial applications. Get more information form  https://www.hwnanomaterial.com/.