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July 6, 2015

The Nanotechnology of Carbon Nanotubes

Multi walled carbon nanotubes can appear either in the form of a coaxial assembly of SWNT similar to a coaxial cable, or as a single sheet of graphite rolled into the shape of a scroll.The diameters of MWNT are typically in the range of 5 nm to 50 nm. The interlayer distance in MWNT is close to the distance between graphene layers in graphite.MWNT are easier to produce in high volume quantities than SWNT. However, the structure of MWNT is less well understood because of its greater complexity and variety. Regions of structural imperfection may diminish its desirable material properties.

The challenge in producing SWNT on a large scale as compared to MWNT is reflected in the prices of SWNT, which currently remain higher than MWNT.SWNT, however, have a performance of up to ten times better, and are outstanding for very specific applications.

Fullerenes and carbon nanotubes (CNTs) are two closely related carbon materials. While fullerenes have bucky-ball structure, CNTs are stripes of graphite rolled up seamlessly into tubes (cylinders). The carbon atoms in a nanotube are arranged in hexagons, similarly to the arrangement of atoms in a sheet of graphite. The electronic properties are fully determined by its helicity (chirality) and diameter. They can have both metallic and semiconducting properties. The typical dimensions of a single wall CNT are: 1 nm in diameter and length of few micrometers. On the other hand, multi-walled CNTs can have diameters up to 100 nm. Recently, super long nanotubes with length of around 1 cm were successfully synthesized.

CNTs are produced by a variety of methods. The most common methods include chemical vapor deposition (CVD), electric arc-discharge, laser ablation of a carbon target, etc. Aligned (forest-like) nanotubes can also be synthesized. Aligned CNTs provide a well-defined structure for some applications. For example, high power density supercapacitors can be built using locally aligned nanotube electrodes.

CNTs play important role in the developing field of nanotechnology. Their excellent electronic transport properties make them good candidates for building blocks in nanoelectronics. The high aspect ratio of nanotubes is favorable in applications based on field emission, like flat panel displays and lamps. Furthermore, the strong mechanical properties and high thermal stability of CNTs improve the properties of matrix materials such as polymers or ceramics. Nanotubes have also been used as an alternative to currently used fillers (e.g. carbon black) to facilitate electrostatic dissipation by increasing the conductivity of polymers. Other studies have been directed towards improving the conductivity of already conducting polymers, thus resulting in a more conductive material.

As already mentioned, the properties of CNTs are fully determined by their exact atomic structure. Thus, in order to build a precise nanotube-based nanoelectronic device with well-defined properties, it is crucial to control the positioning and the atomic (electronic) structure (helicity) of nanotubes already in the growth phase. Some major hurdles still need to be overcome in this field. However, there are many applications where CNT networks are used instead of individual nanotubes. In these cases the properties of the whole nanotube network are determinative. These applications are very promising and a long line of nanotube-based materials and devices are already in the pipeline.

June 30, 2015

Do You Know Gold Nanoparticles?

Ultrasmall, crystalline, and dispersible NiO nanoparticles are prepared for the first time, and it is shown that they are promising candidates as catalysts for electrochemical water oxidation. Using a solvothermal reaction in tert-butanol, very small nickel oxide nanocrystals can be made with sizes tunable from 2.5 to 5 nm and a narrow particle size distribution. The crystals are perfectly dispersible in ethanol even after drying, giving stable transparent colloidal dispersions. The structure of the nanocrystals corresponds to phase-pure stoichiometric nickel(ii) oxide with a partially oxidized surface exhibiting Ni(iii) states. The 3.3 nm nanoparticles demonstrate a remarkably high turn-over frequency of 0.29 s–1 at an overpotential of g = 300 mV for electrochemical water oxidation, outperforming even expensive rare earth iridium oxide catalysts. The unique features of these NiO nanocrystals provide great potential for the preparation of novel composite materials with applications in the field of (photo)electrochemical water splitting. The dispersed colloidal solutions may also find other applications, such as the preparation of uniform hole-conducting layers for organic solar cells.

Gold has always been the one precious material people like best. Due to its intrinsic value, buying the yellow metal has been seen as a good way of securing one’s money. Big players on the market prefer it in the form of bullion, whereas small investors settle themselves with purchasing fine pieces of gold jewelry. In modern times though, gold has ceased to be merely a safe investment opportunity or exchange currency. As a result of extensive research and continuous development, it has been discovered that gold can be used successfully for scientific purposes as well.

One of these special uses of gold refers to what is called ‘nanogold’, ‘colloidal gold’ or ‘gold nanoparticles’, i.e. sub-micrometer-sized particles of gold dispersed in a fluid, usually water. The existence of these special gold particles has been known to people since ancient times, yet it was in 1850s that scientists focused their full attention on them. The main reasons behind this interest for gold nanoparticles are their extraordinary optical, electronic and molecular-recognition properties. These properties allow for the gold nanoparticles to have applications in various fields, including electron microscopy, electronics,Nickel Oxide Nanoparticles,nanotechnology and materials science.

Biological electronic microscopy is one of the areas where gold nanoparticles have been extensively used as contrast agents. They can be associated with many traditional biological probes such as antibodies, lectins, superantigens, glycans, nucleic acids and receptors. Because gold particles having various sizes can be easily spotted in electron micrographs, it is possible for multiple experiments to be conducted simultaneously.

In what concerns the domain of health and medical applications, gold nanoparticles have been successfully used as part of the treatment for some diseases. Rheumatoid arthritis was among the first conditions where use of gold was part of the therapy since it has been found that gold particles implanted near the arthritic hip joints relieve pain. There have also been some in vitro experiments which have proved that gold nanoparticles combined with microwave radiation can destroy the beta-amyloid fibrils and plaque which are characteristic for Alzheimer’s disease. But perhaps the most important medical purpose for which gold nanoparticles can be used is the localization and treatment of cancer. It has already been shown that by directing gold nanoparticles into the nuclei of cancer cells, they can only not hinder them from multiplying, but also kill them.

As we can see, for the modern society of today gold has become more than just merchandise and by buying it we do not just secure our investments, but our health as well. With the help of science, researchers have been able to explore the great latent potential gold has. Just like the professionals in the business whose opinion is of great value for the buyers, specialists in important areas such as medicine can testify about gold’s benefits too.

June 25, 2015

Standards For Nano-Enabled Industries

Single-walled Carbon Nanotubes (SWNTs) are nanometer-diameter cylinders consisting of a single graphene sheet wrapped up to form a tube. Since their discovery in the early 1990s[1, 2], there has been intense activity exploring the electrical properties of these systems and their potential applications in electronics. Experiments and theory have shown that these tubes can be either metals or semiconductors, and their electrical properties can rival, or even exceed, the best metals or semiconductors known. Particularly illuminating have been electrical studies of individual nanotubes and nanotube ropes (small bundles of individual nantoubes). The first studies on metallic tubes were done in 1997[3, 4] and the first on semiconducting tubes in 1998[5]. In the intervening five years, a large number of groups have constructed and measured nanotube devices, and most major universities and industrial laboratories now have at least one group studying their properties. These electrical properties are the subject of this review. The data presented here are taken entirely from work performed by the authors (in collaboration with other researchers), but they can be viewed as representative of the field.

Like the California gold rush of 1849, the emergence of nanotechnology presents both an enormous opportunity and enormous risks. Just as new techniques, rewards, and challenges emerged during the gold rush era, nanotechnology exploration will inevitably lead to the development of new tools to achieve new breakthroughs, the opportunity for creating enormous wealth, and unfortunately, the potential for environmental, health, and safety disasters. Although Single-walled Carbon Nanotubes undoubtedly will create disruptive technologies that will spin off many new jobs, it also has the potential for displacing existing workers unprepared to take on these new technologies.

The first fruits of nano R&D are already being harvested as disciplines as diverse as materials, electronics, biotechnology, and computing rush to exploit nanotechnology’s potential. Many consumers have already become familiar with nano-derived products, such as improved types of cosmetics, fabrics, paints, plastics, or personal electronics.

Nanotechnology offers all-but-unlimited opportunities for those who can develop the next exotic material or electronic component that is cheaper, better, and faster than today’s CMOS devices. It also holds huge promise for those who will create the tools needed to produce these materials and devices. Despite the recession, corporate and government labs around the world continue to invest billions in nanoscience research. Unfortunately, unless the public and private sectors work in cooperation to develop standardized test methods and guidelines, the transition from the laboratory to the marketplace could create many of the same problems as the California gold rush did, particularly for the environment. However, with careful planning, we can have the appropriate terminology, test measurement methods, reporting, and environmental, safety, and health safeguards in place early enough to ward off serious consequences.

Why Are Standards So Important?

Very simply, standards are crucial to achieving a high degree of interoperability, creating order in the marketplace, simplifying production requirements, managing the potential for adverse environmental impacts, and most important, ensuring the safety and health of those developing and using the next generation of materials and devices.

Standards for nano terminology, materials, devices, systems, and processes will help establish order in the marketplace. For R&D researchers and engineers, standards make it possible to make measurements and report data consistently in a way that others can understand clearly. Those responsible for developing standards will be at the forefront in understanding the need for, and creation of, new characterization tools, processes, components, and products to help jump-start this emerging field. This kind of approach can represent a competitive tool in global markets. Creating a standard in advance of the release of a new technology allows both manufacturers and consumers to gain greater confidence in it, promoting greater acceptance and faster adoption.

The following examples illustrate the importance of early standards development.

Carbon Nanotubes

Although some of the more sophisticated electronics and medical advances scientists have envisioned are still years down the road, the development of some nanoscale raw materials, particularly carbon nanotubes (CNTs), is already well underway. Years before CNTs were commercially available, industry observers heard how they would bring significant performance advantages to electronics, enhance materials to make them stronger and lighter, and might even be part of the solution to our energy problems. This industry buzz, plus the massive private and public sector investments in nano research, built interest at every level. In 2000, the late Dr. Richard Smalley spun off his work to form Carbon Nanotechnologies Inc. (now Unidym) with the goal of commercializing his method of producing large batches of high-quality nanotubes. Unfortunately, at that point, there were no manufacturing standards or guidelines for ensuring the reproducibility of the company’s manufacturing process. There were also no known test and measurement guidelines for verifying the reproducibility and proving results on a large scale. Given this, how would the company have assured its customers of the quality of its products? Or just as important, how could customers choose confidently among various manufacturers’ CNTs based on their product description?

Buying carbon nanotubes isn’t like buying baseballs or bananas-it’s impossible to judge their quality just by looking at them. En masse, CNTs basically look like a pile of soot. How can incoming inspectors verify what they have received? How do they know whether they are single-walled or multi-walled tubes? Given the different species of carbon nanotubes now available (tubes that are metal or semiconducting, based on their chirality), most companies looking to purchase nanotubes would have had no basis on which to ensure that what they received is what they ordered. However, with a standard in place, customers have the tools needed to verify the materials they are purchasing.

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 8, 2015

Nano Diamond Powder at Its Best

The unique features of nanodiamonds have demonstrated unprecedented performance in various fields. Nanodiamond powder is a state-of-the-art material widely used in polishing compositions, coatings, lubricants and polymers. Currently nanodiamond powder is rapidly finding its way into biomedicine, Thermal Management in electronics, energy storage, field emission displays and other advanced applications.

Ray’s technology for producing nanodiamonds is based on the laser treating of specially prepared targets containing carbon soot mixed within hydrocarbon media. In contrast to the traditional technology of nano diamond powder synthesis by detonation of explosives in metal reactors, Ray’s method is controllable, environment-friendly and non-hazardous. Ray-nanodiamonds are of much higher purity than detonation nanodiamonds available today in the market. Industrial manufacturing of nanodiamonds by Ray technology will lead to significant reducing the cost, better results in most existing applications, rapid enhancing of Global Nanodiamond Powder Market and appearance of new nanodiamond applications where the purity of powder is of special importance.

In addition, it has developed new approach in the design novel nanodiamond composite materials with desired properties. This technology is based on special nanodiamond surface modification, full disaggregation and covalent bonding between diamond nanocrystals and molecules of chosen material. Uniform introducing nanodiamonds within the medium results in increase of nanodiamond performance in each compound and in the possibility to reduce nanodiamond content and the cost of the composite material. Due to this innovative approach, it has developed low cost and highly efficient nanodiamond based products for various technological processes.

The usability and applicability of nanotechnology is wide-ranging. The principle of nanotechnology that allows man to manipulate the molecular structure of materials has also made it possible for new innovations to flourish. Today, nanotechnology has grown to such an extent that about a thousand products are being developed or manufactured in laboratories all around the world using the technology. Passive nano-materials are already available for the cosmetics and food industry. Carbon allotropes nano-materials are also being used for textile, food packaging, appliances and many other manufacturing sectors.

The building industry has also adopted the use of nano-materials for surface and protective coatings products, using what is called “surface functionalized nano-materials.” Nano-particles like dodecanethiol functionalized gold particles have unique surface chemistries that can be controlled. Their adhesion properties can be changed. Nano-powders can be dispersed to polymers and protective coatings. When these nano-materials are combined with coatings and applied to target surfaces, they change the surface properties and make it more resistant to UV rays, typical corrosion, and many types of damages.

Nanotechnology Innovation: Protective Super-Paints

The coatings industry is stepping up the production of nanotechnology products. Just last year, an Italian paint manufacturer developed superpolymers and protective coatings based on a patented nanotechnology. The results are anti-corrosive fire-resistant super-paints based on nano-clay composites. Nano-clay is a material that has outstanding barrier properties and is very cost-efficient in its application. The anti-corrosive coatings will soon be in the market this 2010.

Many other anti-corrosion formulations based on nano-materials are also used in the construction and underwater industries. Heavy machinery painting applications often require the best performance in protective coatings. In the oil extraction and energy generation industries, nano-tech protective coatings that are resistant to fluctuating and extreme temperatures are also being used.

Excellent Surface Protection with Nanotechnology

In terms of surface protection, nanotechnology is often used to formulate nano-scale coatings that make the target surfaces high-performing and resistant to damages.

The Diamon Fusion® nanotechnology is one good example of this technological advancement. Theirs is a patented technology to manufacture capped silicone films. Using a patented chemical vapor deposition process, the technique is employed to silicon-dioxide-based surfaces. These coatings are also effective on glass, ceramic, granite or porcelain surfaces. The technology involves a two-stage chemical process. The first stage creates cross-linked films in silica-treated surfaces. The second stage caps the surface. The coatings thereby increase the surface’ ability to repel water intrusion. Aside from this unique waterproofing property, the protective coatings can also provide the surface with good resistance against surface contaminants. In essence, the protective coatings imbue the surface with easy self-cleaning abilities.

Diamon Fusion® coatings are applied in an air-tight room using a vapor deposition system for high-volume and batch applications. It can also be hand-applied as a liquid product to smaller projects. Whatever method of application was used, the coatings act in the same way. They create cross-linked and branched, capped silicone films in the surface. The final film is clear-colored and seals the surface tightly. The bond formed by the chemical process is unbreakable from then on.

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

May 26, 2015

Types of Chemical Heater and Silicon Carbide Whisker

Silicon Carbide is the only chemical compound of carbon and silicon. It was originally produced by a high temperature electro-chemical reaction of sand and carbon. Silicon carbide is an excellent abrasive and has been produced and made into grinding wheels and other abrasive products for over one hundred years. Today the material has been developed into a high quality technical grade ceramic with very good mechanical properties.It is used in abrasives,refractories,ceramics,and numerous high-performance applications. Silicon carbide whisker can also be made an electrical conductor and has applications in resistance heating, flame igniters and electronic components. Structural and wear applications are constantly developing.

Chemical heater and etch process are important terms that must be learned by people and businesses in the semiconductor industry. In this article, I am sharing about the types of chemical heaters used in the wet process system as well as the silicon nitride etch process.

Types of chemical heater

Quartz – Gas Heater — a system that is designed to meet the growing demand for heated high purity gasses. It has the capacity of heating a wide range of gases including: Ammonia (NH3), Helium (He), Argon (Ar), Hydrogen (H2), Arsine (AsH3),Hydrogen Bromide (HBr), Boron Trichloride (BCl3),Hydrogen Chloride (HCl), Carbon Dioxide (CO2), Nitrogen (N2),Carbon Monoxide (CO), Chlorine (Cl2), Nitrous Oxide (N2O), Oxygen (O2),Disilane (Si2H6), Sulfur Dioxide (SO2),Methylsilane (SiH3CH3)

Quartz – Fluid Heater — used in the semiconductor industry and its traditional application includes recirculation loop, either as the sole head source or a combination of a heated quartz tank.

SiC – HF & KOH Heater — designed for heating HF (hydrofluoric acide), KOH (potassium hydroxide), and other high PH chemistries. It uses high purity Silicon Carbide (SiC) as a heat transfer material because it has excellent heat transfer properties and eliminates the risk of contamination due to Teflon breakdown.
Interesting Facts about the Silicon Nitride Etch process

To be able to achieve the greatest etch rates and best selectivity, the phosphoric acid should have the highest ratio of water at a given temperature. For as long as the boil point is maintained, the etch rate of both Si3N4 and SiO2 can be precisely controlled.

Maintaining a boiling solution is one of the challenges in the etch process. When phosphoric acid is heated, the water solution begins boiling off. When temperature is not maintained, it affects the etching process as the acid concentration increase. Wet etch companies use a standard temperature controller to maintain temperature, but the water concentration will decrease and will change the etch rates. As a solution, wet etch process engineers use water addition system.

A technology called closed “reflux” system is used and it is created above the bath using condensing collar and a lid – this is to minimize water addition.

The chemical fumes and high temperatures that Nitride Etch tanks are subjected to are known to decrease bath life substantially by attacking the sealant that prevents liquid and fumes from entering the heater area. This problem has been addressed through the use of aquaseal.

Quartz Nitride Reflux system is engineered to address the unique needs of the silicon nitride etch process. It gives the following benefits to customers: process uniformity, lot-to-lot repeatability, prevents stratification.

May 11, 2015May 11, 2015

The Tern Nano-Technology Article

Some time ago I ran across the tern Nano-Technology while searching the net. According to Wikipedia, a brief description is “the control of matter on an atomic and molecular scale”. The Nano-scale is so small it is hard to imagine. To give you some idea a typical penny is about 19,000,000 Nano meters in diameter.

Even as small as it is, Scientists and Engineers have discovered how to manage and manipulate these tiny Nano Element Particles into some very useful and amazing new materials. The other amazing aspect of Nano-Technology is that when elements are reduced to a Nano-scale their physical characteristics change. Solids turn to liquids, stable materials turn combustible, insulators become conductors and opaque substances become transparent. With this knowledge there are and will be some amazing new products introduced into our daily lives.

Although most experts think that the changes brought about by this new science would improve our way of living, some are not so sure. I still continued my quest for new products and would do a search every so often just to see what was out there or what was new. During one of those searches, I ran across a company called Cermet Labs Inc. Their web site was very impressive and the information presented on the site was interesting. They made some claims that I am sure we have all heard before, however since it involved Nano-Technology I read on.

They seemed to have a variety of evidence to back up their statements about what their product would do. I considered the independent lab tests presented and the data on the field testing. It sounded reasonable and I decided to give them a call for more information. As it turns out they were located in a Detroit suburb which was within easy driving distance for me. I make an appointment and met with their CEO and Sales Manager. They made a very detailed presentation about the science behind their product. I understood some of it and some I did not. I guess wasn’t as concerned about how to build a watch, just could I get the correct time. The end result was that I felt it was a reputable company and product; however I still wanted to prove to myself that the claims were true.

The old seeing is believing theory. We went out to the parking lot and injected a 10ml syringe into the oil filler inlet of my car. I discovered later we really did not install it exactly as the instructions called for but it was in the engine now so I was anxious to see the results. Since I hadn’t kept actuate records on my mileage I decided I had better start so I could have a before number to compare to. When I started to keep track of my mileage the car had 205,427 miles on it. I though the car ran well and was getting reasonable mileage. During the first 636 miles the mpg was 21.18 which I though was not bad for a full size 96 Buick Park Avenue.

I was told that during the first 2000 miles of the run in period my mileage could vary. After 1912 miles I was pleased to find that my mpg was now at 25.14. Also it seemed that the car just ran smoother and had reasonably good power. I stopped keeping track for a while and just went about my normal driving. One day it seemed like I was going through a tank of gas quicker that usual. So I decided to check a tank full just to see if anything had changed. My odometer now read 213056 miles and the tank full of gas gave me 24.63 miles per gallon.

According to the EPA rating when the car is new, it should produce 17 and 27 highway. Considering the age and I believe I got this car miles mileage and the best performance is possible. I also believe that, the car’s performance and it is a ceramic ceramic processing laboratory reason. As a side note, I have to laugh when I saw a new car, claiming they will get 27 miles per gallon, $30000 worth of TV advertising. I can fill the tank at $30000 600. It is about 230000 miles.

May 4, 2015

Low Cost Synthesis of Silicon Carbide Nanopowders

Among modern ceramic materials, silicon carbide (SiC) and silicon nitride (Si3N4) has been successfully used in a variety of high-tech applications. SiC provides the effective combination of mechanical properties. It is widely used as an abrasive material and structure. It has high hardness, chemical inertness, than the melting temperature of the steel wear and oxidation of it for serious conditions such as high temperature sealing valve, rocket nozzle and wire drawing die and extrusion die for bearing applications because of its good wear resistance and corrosion resistance. In the tube by SiC to find its thermal properties and creep resistance of high temperature and hot electron exchange. The heating element from SiC. They can produce a high temperature of 1650 DEG C and medium in the air or inert considerable life. However, with any contact with water or hydrocarbon gas, can influence their age.

Silicon nitride has comparatively lower oxidation resistance and higher thermal conductivity than SiC. Major applications of silicon nitride are as automotive and gas turbine engine parts. It has high strength, fracture toughness and refractoriness which are required properties for ball bearings, anti-friction rollers. It performs remarkably when exposed to molten metal and/or slag.

A combined form of silicon carbide and nitride has been developed as silicon carbide grains bonded in silicon nitride matrix. This Si3N4-bonded silicon carbide is used for some critical applications where very high thermal shock resistance is required. For instance, in particular case of flame-out engine start-up, temperature reaches from ambient to 1600 °C in few seconds followed by an abrupt decrement to 900 °C in less than one second. Si3N4-bonded silicon carbide exclusively endures these conditions.

Traditional methods to produce these ceramic materials are energy intensive and hence expensive. For example, the Acheson process, which is the most widely adapted method to produce commercial-grade SiC, essentially takes 6 – 12 kWh to yield one kg of SiC. An inexpensive method, that uses low cost agro-industrial byproduct, is the pyrolysis of rice husks, first carried out by Lee and Cutler in 1975. Since then many researchers have discussed and used various process routes and modifications to obtain Silicon Carbide Nanopowders and/or silicon nitride, either in particulate or in whisker form, from rice husks.

Morphological studies on RH reveal that micron size silica particles are distributed in cellulosic part of RH. When these silica particles are made to react with carbon in biomass part of RH under specific experimental conditions, silicon carbide can result. Moreover, besides silicon carbide, modifications in process mechanism lead to formation of some other industrially useful products, viz. silicon nitride, silicon oxynitride (Si2N2O), ultra-fine silica, and solar-cell grade silicon.

Related reading: nano particles nano oxides

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.