Silver Nanoparticles Antimicrobial – Page 2 – Silver Nanoparticles Antimicrobial,Copper Oxide Nanoparticles,Gold Nanopowder

July 27, 2015

Information of Most Versatile Precious Metal Ruthenium

Ruthenium metal powders are called “two ruthenium Foix.” When sunlight, molecular diRuthenium Foix will change shape into a semi-stable state, but this state is very safe. They can be stored indefinitely heat by means of a catalyst, which in turn can be restored to its original shape, releasing tremendous heat stored. The heat can be used to heat the house.

Although alphabetically last in a list of precious metals, ruthenium is considered to be the most versatile of this group of elements. There is a total of six precious metals found within the platinum group, with ruthenium being the most versatile.

Ruthenium is a hard white-colored metal that has four crystallization varieties. Ruthenium does not tarnish under general circumstances, but will quickly oxidize quickly with exposure to air. Two methods of plating will improve its durability, these are known as electrodeposition and thermal decomposition.

Alloys comprised of ruthenium and palladium or ruthenium and platinum are commonly used as materials for electrical contacts because of the excellent wear resistance. Ruthenium is known to be very effective when used as a hardener when used as an alloy for palladium or platinum products. Adding ruthenium to titanium, the resulting alloy has a significantly improved resistance to corrosion.

There are other applications for ruthenium, including manufacture of film chip resistors, as an alloy with gold for high end jewelry, industrial turbine blades for aircraft engines (because it is a high temperature super alloy), tips for high end fountain pens, as part of a chemical process for mixed-metal oxide anodes or removal of hydrogen sulfide during industrial manufacture; parts of optical sensor devices; and radiography equipment (such as that required for eye sensors).

Ruthenium is found in various ores in the Ural Mountain range in Russia, as well as parts of North America and South America. Other locations, including Sudbury in Ontario, Canada, in pentlandite, (which is an sulfide comprised of iron and nickel) as well as small areas of South Africa, in pyroxenite (which is an ultrabasic igneous rock formation) also contain sources of ruthenium. This precious metal is found alongside the other five precious metals that are included within the platinum group.

Ruthenium is derived for commercial purposes as a by- product when nickel and copper is processed. This is similar to the way that the other platinum family precious metals are obtained. Direct processing of certain platinum ores can also be a way to obtain ruthenium. Isolating ruthenium can only be done following a complex chemical process. This process will ultimately yield a powder form which can be consolidated through argon arc-welding techniques.

Ruthenium is rather rare, ranking 74th among all of the chemical metal elements, making it one of the most rare elements. Worldwide, there are approximately 5000 tons available, and this amount is mined at a rate of approximately 12 tons per year. Ruthenium is valued at around $1000 USD per troy ounce.

July 14, 2015

The Antimicrobial Features of Nano Silver

Antibacterial coating nano silver is regarded as a new generation of antibacterial agents and has great potential to be utilized in antibacterial surface coatings for medical devices, food package and industrial pipes. However, disadvantages such as easy aggregation, uncontrollable release of silver ions and potential cytotoxicity greatly hinder its uses. Recently, polymers possessing unique functions have been employed to fabricate nanocomposite coatings with nanosilver for better biocompatibility and enhanced antibacterial activity. This review starts with progress on antibacterial mechanism and cytotoxic effects of nanosilver. Antibacterial functions of polymers are subsequently discussed. Advances of fabrication of polymer/nanosilver composite coatings for antibacterial applications are surveyed. Finally, conclusions and perspectives, in particular future directions of polymer/nanosilver composite coatings for antibacterial applications are proposed. It is expected that this review is able to provide the updated accomplishments of the polymer/nanosilver composite coatings for antibacterial applications while attracting great interest of research and development in this area.

Nanometer (nm) is the second smallest micron unit of measurement, a nanometer is a millionth millimeter, namely nanometer, which is one billionth of a meter. Nano-silver is the use of cutting-edge nanotechnology silver nano, nanotechnology have enabled the state of nano silver sterilization ability to produce a qualitative leap, little nanosilver can have a strong bactericidal effect, can kill in minutes Death 650 kinds of bacteria, broad-spectrum bactericidal without any resistance, to promote wound healing, cell growth and repair of damaged cells without any toxicity, skin irritation also did not find any, which gives wide Application to antibacterial nano silver has opened up broad prospects, is the latest generation of natural antibacterial agent, nano-silver sterilization has the following characteristics:
Broad-spectrum antibiotic

Silver nanoparticles directly into the cell and oxygen metabolizing enzymes (-SH) combine to make cell suffocated unique mechanism of action, can kill most bacteria in contact with, fungi, mold spores and other microorganisms. After eight domestic authorities found: their drug-resistant pathogens, such as E. coli, resistant Staphylococcus aureus resistant Pseudomonas aeruginosa, Streptococcus pyogenes resistant enterococci, anaerobic bacteria, which are full of antibacterial activity; surface burns and trauma of common bacteria such as Staphylococcus aureus, Escherichia coli, Pseudomonas aeruginosa, Candida albicans and other G +, G- pathogens have a bactericidal effect; Chlamydia trachomatis, a sexually transmitted disease caused by Neisseria gonorrhoeae also has a strong bactericidal effect.

An antibiotic can kill about six kinds of pathogens, and nano-silver can kill hundreds of pathogenic microorganisms. Kill bacteria, fungi, trichomoniasis, branch / chlamydia, gonorrhea, strong bactericidal effect of antibiotic resistant bacteria have the same role in the killing!
Potent bactericidal

It found, Ag 650 kinds of bacteria can kill within minutes. Nano silver particles and pathogens in the cell wall / membrane-bound, directly into the cell and quickly combine with oxygen metabolizing enzyme thiol group (-SH), inactivating the enzyme, blocking the respiratory metabolism to suffocate it. Unique sterilization mechanism, making silver nanoparticles at low concentrations can rapidly kill pathogens.
Permeable

Silver nanoparticles with superior permeability, can rapidly penetrate the subcutaneous 2mm sterilization, common bacteria, stubborn bacteria, resistant bacteria as well as the deeper tissue infections caused by fungi have a good bactericidal effect.
Repair and regeneration

Nano-silver can promote wound healing, promoting repair and regeneration of damaged cells, to rot myogenic, anti-inflammatory improve microcirculation trauma to surrounding tissue, effectively activate and promote the growth of tissue cells, accelerate wound healing and reduce scarring generated.
Antibacterial lasting

Silver nanoparticles use patented technology, outer layer of protective film can be gradually released in the human body, so anti-bacterial effect.
No drug resistance

Nano-silver is a non-antibiotic agents: nano-silver can kill a variety of pathogenic microorganisms, more than antibiotics, antibacterial mechanism of silver nanoparticles unique 10nm size can quickly kill bacteria directly to the loss of reproductive ability, therefore, can not produce the next generation of drug resistance, can effectively avoid drug resistance and cause recurrent permanently.

Silver used in modern medicine
In 1884, the German obstetrician F. Crede (Claude), the concentration of 1% silver nitrate solution was dropped in the eyes of newborns to prevent blindness caused by neonatal conjunctivitis, infant blindness prevalence dropped from 10% 0.2 percent, until today, many countries still using Crede prophylaxis.

In 1893, C. Von Nageli (Nag column) through a systematic study, first reported in the metal (especially silver) bacteria and other lower organisms lethal effect, so there may be a silver disinfectant. Since then, the use of silver into the modern era.

Silver used in modern medicine in many forms, including:
(1) silver: 0.5% silver nitrate standard solution for treating burns and wounds; 10-20% of the silver nitrate solution applied, can be used for the treatment of cervical erosion.
(2) Silver sulfadiazine: Columbia University Charles L. Fox (Fox) professor and sulfadiazine silver compound, silver sulfadiazine generated activity than the individual sulfa strong activity at least 50 times. 1968, silver sulfadiazine (Sulfadiazine Silver) introduced to the market, because of its variety of bacteria, fungi and efficient role in the killing has, naturally, painless way to fully repair the wound site without skin grafting, has become the treatment of trauma ( such as burn) important drugs. It has now been included in the national basic medical insurance drug list.
(3) colloidal silver or silver protein: an effective topical anti-infective substances, colloidal silver can be used for gynecological sterilization.
(4) silver plated materials: silver, founder of the research, AB Flick (Fleck), Dr. Silver has developed a product that is coated with a layer of silver on the bandage, used as a dressing. Inspired by him, people use silver antimicrobial resistance, have developed a silver-plated sutures, silver catheter. Currently the United States has a dozen silver-containing products, as a medical device received FDA marketing approval, including silver dressings, silver gelatin, silver powder and other types of medical products.

June 15, 2015

Do You Know Antibacterial Silver Nanoparticles?

The antimicrobial activity of Silver Nanoparticles Antimicrobial against E. coli was investigated as a model for Gram-negative bacteria. Bacteriological tests were performed in Luria–Bertani (LB) medium on solid agar plates and in liquid systems supplemented with different concentrations of nanosized silver particles. These particles were shown to be an effective bactericide. Scanning and transmission electron microscopy (SEM and TEM) were used to study the biocidal action of this nanoscale material. The results confirmed that the treated E. coli cells were damaged, showing formation of “pits” in the cell wall of the bacteria, while the silver nanoparticles were found to accumulate in the bacterial membrane. A membrane with such a morphology exhibits a significant increase in permeability, resulting in death of the cell. These nontoxic nanomaterials, which can be prepared in a simple and cost-effective manner, may be suitable for the formulation of new types of bactericidal materials.

There are some bacteria that are not effectively killed by the conventional antibiotics including many strains of gram-negative bacteria. However the innovative world of science and the need of developing an effective way to cope with this situation has lead scientist to manage a new technology in this regard.

Rani Pattabi and her colleagues at Mangalore University, explains in the international journal of nanoparticles that an electron beam when blasted on a silver nitrate solution can generate nanoparticles.

These particles are shown to be effective against gram-negative species that are not affected by conventional antibacterial agents.

The researchers in India also pointed that these silver nanoparticles are effective against gram-positive bacteria, such as resistant strains of Staphylococcus aureus and Streptococcus pneumoniae and also effective for treating gram-negative Escherichia coli and Pseudomonas aeruginosa.The problem that is threatening human health is resistance to the existing conventional antibiotics. Therefore the chemists all around the world are desperately trying to develop newer compounds that can easily be bactericidal for strains such as MRSA (methicillin or multiple-resistant Staphylococcus aureus) and E. coli O157.

Since the ancient times, silver has been renowned for its bactericidal activities.

Therefore a technological advancement in the use of silver means a major step forward and a promise for a wide range of applications of silver as anti bacterial agent in the times where antibiotic resistance is proving to be an obstacle for anti bacterial use. Thus the emergence of silver nanoparticles and other such bacteriostatic agents have become a new industrial revolution.

The experimentation involving the radiations to split the silver compounds to release silver ions that will clump together and form nanoparticles, have been taken as a challenge by the researchers. The target was in fact to get a new approach that avoids the need for costly and hazardous reducing agents and that these can be used to get particles of a controlled size that controls its properties as well.

So Pattabi and colleagues used electron beam technology to irradiate silver nitrate solutions in a biocompatible polymer that was polyvinyl alcohol, to form silver nanoparticles.

The Preliminary tests have shown that silver nanoparticles produced by this straightforward, non-toxic method are indeed highly active against S. aureus, E. coli, and P. aeruginosa.

Now we can imagine that our shoes, socks or even the keyboard we are using may be impregnated with silver nanoparticles that can kill some bacteria and might as well prevent the spread of infection among computer users.

These can be the frontline defenses such as these environmentally benign and cost-effective antibacterial compounds and these can prevent spreading the infections through contact with computer keyboard, phones and other devices.

June 1, 2015

An Introuduction of Aluminum Oxide Nanopowder

Aluminum oxide nanopowder Product Features:US3023 g-phase nano-Al2O3 with small size, high activity and low melting temperature, it can be used for producing synthetic sapphire with the method of thermal melting techniques; the g-phase nano-Al2O3 with large surface area and high catalytic activity, it can be made into microporous spherical structure or honeycomb structure of catalytic materials. These kinds of structures can be excellent catalyst carriers. If used as industrial catalysts, they will be the main materials for petroleum refining, petrochemical and automotive exhaust purification. In addition, the g-phase nano-Al2O3 can be used as analytical reagent.

Aqueous Dispersions

NanoArc® Aluminum Oxide nanoparticles are available as concentrated (up to 50 wt%) dispersions in DI water. The aqueous NanoArc® Aluminum Oxide dispersions feature proprietary surface treatment technology to enable formulation of the nanoparticles into systems ranging from pH 4 to 10.

The technology also ensures compatibility of the NanoArc® Aluminum Oxide nanoparticles with aqueous formulations containing emulsion resins, both in-can and post-cure.

In addition, untreated NanoArc® Aluminum Oxide is available as a low pH (< 5) aqueous dispersion for applications not requiring the compatibility surface treatment. Solvent Dispersions Dispersions of NanoArc® Aluminum Oxide nanoparticles are available as concentrates (up to 50 wt%) in polar hydrocarbon solvents such as PMA (propylene glycol methyl ether acetate), nonpolar solvents such as mineral spirits, and protic solvents such as alkoxyethers. The NanoArc® Aluminum Oxide dispersions feature surface treatment technologies designed specifically for the solvent class, and tailored to be compatible with a wide range of application formulations employing solvents in these classes. In addition, custom dispersions of NanoArc® Aluminum Oxide can be provided for specific solvent types or application needs (e.g. non-volatile liquids, plasticizers, etc.). Monomer Dispersions NanoArc® Aluminum Oxide nanoparticles are available as concentrated (30 wt%) dispersions in low viscosity acrylate monomers such as TPGDA (tripropyleneglycol diacrylate) and HDDA (1,6-hexanediol diacrylate). These dispersions can be used to incorporate NanoArc® Aluminum Oxide nanoparticles into a wide variety of UV-cured coating formulations. The NanoArc® Aluminum Oxide nanoparticles are surface treated for compatibility, and do not interfere with the radiation cure process of the coatings. Other low viscosity acrylate monomer dispersions of NanoArc® Aluminum Oxide are also available on a custom basis. Custom Dispersions Nanophase metal oxide nanoparticles are available in a variety of concentrated dispersion forms, each featuring proprietary surface treatment technology to ensure complete dispersion to the primary particles and to prevent any aggregation upon incorporation into application systems. Related reading: nano diamond powder Silver Nanoparticles Antimicrobial

April 27, 2015

How to Evaluate Nickel Alloys

When buying nickel Metal Alloy Nanoparticles it is important to keep a checklist, you should check what different traits are important. Considering the magnetic properties, oxidation and sulfuration resistance, held in extreme weather, the metal’s hardness and resistance to stripe rust quality. These characteristics are important, stainless steel or nickel alloy in the choice to see. Today I will focus on three kinds of quality, the most representative: mechanical properties, manufacturing and cleaning, and erosion resistance.

Mechanical Properties

Before putting in an order, talk to an expert about what diverse temperatures the nickel alloy of interest performs well in. You need the product to work effectively whether it is positioned in a room emitting extreme heat or one maintaining consistent, comfortable room temperature. The operation of the metal should not change. This is essential to your business operations. You cannot have machinery suddenly stop functioning due to a temperature change. A breakdown of equipment puts a dent into your earnings and causes you to cough up money towards repairs.

Fabrication and Cleaning

Fabricating metal refers to how a piece is cut, bent and is put together through welding, fasteners and adhesives producing a certain metal finish. The cleaning aspect relates to the fabrication process for it is dependent on the finish.

Different metal finishes result in a wide degree of cleaning ease. You need to test the one you want before buying. Find a piece with the look you desire and incorporates a cleaning degree you are comfortable with. Just remember, most high quality nickel alloys display a gleaming finish even when placed in a harsh environment while lower quality metals tarnish, fade and exhibit a lack of sparkle.

Erosion Resistance

Using a type of material that cracks, falls apart and rusts is a problem. These defects affect the entire success rate of a business that depends on stainless steel machinery. You cannot keep stopping and starting whenever something breaks down. Having a reliable, strong, erosion resistance material keeps your work moving along smoothly.

Investing in high quality materials can make the difference between your financial situation and peace of mind.The better the quality, the more you pay for the repair and replacement costs, downtime.This allows you to target time and allows you to run your business without additional grief and money.To understand more about the types of metal and how the poor performance of the people from the rest.