Wednesday, September 7, 2011

Very Interesting: Alligator fat could be used to make biodiesel

(Taken from: http://chemistrynewsarticles.blogspot.com/)

In addition to being a novelty food, alligators could also provide a feedstock for biodiesel. Every year, the alligator meat industry disposes of about 15 million pounds of alligator fat in landfills. Now scientists have found that oil can be extracted from the fat and used to make a high-quality biodiesel.


The researchers, Rakesh Bajpai and coauthors from the University of Louisiana, have published their study on the possibility of using alligator fat as fuel in a recent issue of the American Chemical Society journal Industrial & Engineering Chemistry Research.


In 2008, the US produced about 700 million gallons of biodiesel to help supply some of the 45 billion gallons of diesel consumed that year. Most of the biodiesel came from soybean oil. Due to concerns that using food crops to produce fuels will raise the price of food, scientists have been investigating alternative feedstocks, including sewage sludge, Chinese tallow, and used vegetable oil.

By showing in experiments that oil extracted from alligator fat meets nearly all of the official standards for high-quality biodiesel, the Louisiana researchers have added another feedstock to the list. The scientists explained that alligator fat has a high lipid content, and the lipids could be recovered by microwaving frozen samples and by using a chemical solvent.

Although it would play a small role in biodiesel production if it is ever to be used, alligator fat could have an advantage of lower processing costs compared to some other feedstocks since it is a waste product.



Tuesday, July 6, 2010

Chemistry Poem

Ek Kavita Chemistry ke naam............ek website se lee hai... aur sach me kya khub likhi hai.........
Wah bhai wah.......

Na Ye Chemistry Hoti

Na Mein Student Hota

Na Ye Lab Hoti

Na Ye Accident Hota

Abhi Practical Mein Aaye Nazar Ek Ladki

Sundar Thi Naak Uski Test Tube Jaisi

Baton Mein Uski Glucose Ki Mithas Thi

Sanson Mein Ester Ki Khushbu Bhi Sath Thi

Aankhon Se Jhalakta Tha

Kuch Is Taranh Ka Pyaar

Bin Piye Hi Ho Jata Tha

Alcohol Ka Khumar

Benzene Sa Hota Tha

Uski Presence Ka Ehsas

Andhere Mein Hota Tha

Radium Ka Abhas

Nazrein Mileen, Reaction Hua

Kuch Is Taranh Love Ka Production Hua

Lagne Lage Us Ke Ghar Ke Chakkar Aise

Nucleus Ke Charon Taraf Electron Hon Jaise

Us Din Hamare Test Ka Confirmation Hua

Jab Uske Daddy Se Hamara Introduction Hua

Sun Kar Hamari Baat Woh Aise Uchal Pare

Ignition Tube Mein Jaise Sodium Bharak Uthe

Woh Bole, Hosh Mein Aao, Pahchano Apni Auqat

Iron Mil Nahin Sakta Kabhi Gold Ke Sath

Ye Sun Kar Tuta Hamare Armanon Bhara Beaker

Aur Hum Chup Rahe Benzaldehyde Ka Karwa Ghoont Pi Kar

Ab Us Ki Yaadon Ke Siwa Hamara Kam Chalta Na Tha

Tuesday, March 23, 2010

Some Amazing Facts Of Chemistry!!!


  • A litre of vinegar is heavier in winter than in summer.

  • A barrel of juice or wine would take about a year or two to ferment naturally into vinegar.


  • It is easier to swim in a sea rather than in a river because the density of sea water is more compared to that of a river due to dissolved salts.


  • The world's most expensive water is heavy water used as moderator in nuclear reactors.


  • TCDD is a man-made chemical which is 150,000 times more ...more.... deadly than cyanide.

  • Nitrous oxide can make you laugh. That is why it is called laughing gas.

  • Saccharin is 500 to 700 times more sweeter than sugar. 



  • Solid carbon dioxide is called dry ice, because when it melts it does not change into liquid but vapourises directly.


  • Ice does not melt when kept in liquid ammonia.


  • Quick silver is not silver, but it is another name of mercury. It is so heavy that piece of iron floats on its surface.


  • Perfumed talcum powder is made from mineral called Talc. It is the softest possible mineral known to man.
Now some magic....just try.....

  • Take any three figure number in which the first figure is larger than the last, say 521. Reverse it, making 125 and subtract the smaller from the larger, making 396. Now add the result to the same number reversed, 693. The answer is 1089, and will be 1089 whatever number you start with.

  • It is possible to see a rainbow as a complete circle from an aeroplane.

Monday, March 22, 2010

Chemistry Animations

Dear Friends,


Please visit the below mentioned site:


http://dwb4.unl.edu/chemAnime/index.htm


This is really an excellent site for chemistry students.
This site provides very good animated explaination on basic fundamentals of Chemistry.

I know that you will enjoy this site...........

Saturday, March 20, 2010

Nitinol: Shape Memory Alloy (SMA)

Nickel-Titanium, also known as Nitinol, is a metal alloy of nickel and titanium, where the two elements are present in roughly equal amounts.

Nitinol alloys exhibit two closely related and unique properties: shape memory and superelasticity (also called pseudoelasticity). Shape memory refers to the ability of Nitinol to undergo deformation at one temperature, then recover its original, undeformed shape upon heating above its "transformation temperature". Superelasticity occurs at a narrow temperature range just above its transformation temperature; in this case, no heating is necessary to cause the undeformed shape to recover, and the material exhibits enormous elasticity, some 10-30 times that of ordinary metal.

Nitinol's extraordinary ability to accommodate large strains, coupled with its physiological and chemical compatibility with the human body have made it one of the most commonly used materials in medical device engineering and design.

HISTORY

The term Nitinol is derived from its composition and its place of discovery: (Nickel Titanium Naval Ordnance Laboratory). William Buehler along with Frederick Wang, discovered its properties during research at the Naval Ordnance Laboratory in 1962.

While the potential applications for Nitinol were realized immediately, practical efforts to commercialize the alloy didn't take place until a decade later. This delay was largely because of the extraordinary difficulty of melting, processing and machining the alloy. Even these efforts encountered financial challenges that weren't really overcome until the 1990s, when these practical difficulties finally began to be resolved.

The discovery of the shape-memory effect in general dates back to 1932 when Swedish researcher Arne Olander first observed the property in gold-cadmium alloys. The same effect was observed in Cu-Zn in the early 1950s.

HOW IT WORKS

Nitinol's unusual properties are derived from a reversible, solid state phase transformation known as a martensitic transformation.

At high temperatures, Nitinol assumes an interpenetrating simple cubic crystal structure referred to as austenite (also known as the parent phase). At low temperatures, Nitinol spontaneously transforms to a more complicated “monoclinic” crystal structure known as martensite. The temperature at which austenite transforms to martensite is generally referred to as the transformation temperature.

Crucial to Nitinol’s properties are two key aspects of this phase transformation: 

  1. First is that the transformation is “reversible,” meaning that heating above the transformation temperature will revert the crystal structure to the simpler austenite phase.

  2. The second key point is that the transformation in both directions is instantaneous.
Martensite's crystal structure (known as a monoclinic, or B19' structure) has the unique ability to undergo limited deformation substantially without breaking atomic bonds. It is able to undergo about 6-8% strain in this manner. When martensite is reverted to Austenite by heating, the original austenitic structure is returned, regardless of whether the martensite phase was deformed. Thus the name "shape memory" refers to the fact that the shape of the high temperature austenite phase is "remembered," even though the alloy is severely deformed at a lower temperature.

A great deal of force can be produced by preventing the reversion of deformed martensite to austenite, in many cases, more than 100,000 psi. One of the reasons that Nitinol works so hard to return its original shape is that it is not just an ordinary metal alloy, but what is known as an intermetallic compound.

In an ordinary alloy, the constituents are randomly positioned on the crystal lattice; in an intermetallic compound, the atoms (in this case, nickel and titanium) have very specific locations in the lattice. The fact that Nitinol is an intermetallic is largely responsible for the difficulty in fabricating devices made from the alloy.

The scenario described above (cooling austenite to form martensite, deforming the martensite, then heating to revert to austenite, thus returning the original, undeformed shape) is known as the thermal shape memory effect.

A second effect, called superelasticity or pseudoelasticity is also observed in Nitinol. This effect is the direct result of the fact that martensite can be formed by applying a stress as well as by cooling. Thus in a certain temperature range, one can apply a stress to austenite, causing martensite to form while at the same time changing shape. In this case, as soon as the stress is removed, the Nitinol will spontaneously return to its original shape. In this mode of use, Nitinol behaves like a super spring, possessing an elastic range some 10 to 30 times greater than that of a normal spring material.

Nitinol is typically composed of approximately 50 to 51% nickel by atomic percent (55 to 56% weight percent). Making small changes in the composition can change the transition temperature of the alloy significantly. One can control the Af temperature in Nitinol to some extent, but convenient superelastic temperature ranges are from about -20 degrees to +60 degrees C.

One often-encountered complication regarding Nitinol is the so-called R-Phase. The R-Phase is another martensitic phase that competes with the martensite phase mentioned above. Because it does not offer the large memory effects of the martensite phase, it is, more often than not, an annoyance.

APPLICATIONS



There are four commonly used types of applications for Nitinol.

  1. Free Recovery: Nitinol is deformed at a low temperature, and heated to recover its original shape.

  2. Constrained Recovery: The same, except that recovery is rigidly prevented, and thus a stress is generated.

  3. Work Production: Here the alloy is allowed to recover, but to do so it must act against a force (thus doing work).

  4. Superelasticity: As discussed above, here the Nitinol acts as a super spring.
In 1989 a survey was conducted in the United States and Canada that involved seven organizations. The survey focused on predicting the future technology, market, and applications of SMA's. The companies predicted the following uses of Nitinol in a decreasing order of importance: (1) Couplings, (2) Biomedical and medical, (3) Toys, demonstration, novelty items, (4) Actuators, (5) Heat Engines, (6) Sensors, (7) Cryogenically activated die and bubble memory sockets, and finally (8) lifting devices. 

  • In colorectal surgery, the material is used in devices for reconnecting the intestine after removing the pathology.

  • In dentistry, the material is used in orthodontics for brackets and wires connecting the teeth. Once the SMA is placed in the mouth its temperature rises to ambient body temperature. This causes the Nitinol to contract back to its original shape applying a constant force to move the teeth. These SMA wires don't need to be retightened as often as they can contract as the teeth move unlike conventional stainless steel wires. Additionally, Nitinol can be used in endodontics, where Nitinol files are used to clean and shape the root canals during the root canal procedure.

  • Due to the fact it can change shapes it is also used as a golf club insert.

  • Due to the property of remembering the shape at different temperature, it is used in space antenna to save the space in space craft.

  • Another significant application of Nitinol in medicine is in stents: A collapsed stent can be inserted into a vein and heated (returning to its original expanded shape) helping to improve blood flow. Also, as a replacement for sutures where Nitinol wire can be weaved through two structures then allowed to transform into its preformed shape which should hold the structures in place.

  • Nitinol is highly biocompatible and has properties suitable for use in orthopaedic implants.

  • Nitinol is also popular in extremely resilient glasses frames. It is also used in some mechanical watch springs.

  • It can be used as a temperature control system; as it changes shape, it can activate a switch or a variable resistor to control the temperature.

  • It is used in cell-phone technology as a retractible antenna, or microphone boom, due to its highly flexible & mechanical memory nature.

  • It is used in some novelty products, such as self-bending spoons which can be used by amateur and stage magicians to demonstrate "psychic" powers or as a practical joke, as the spoon will bend itself when used to stir tea, coffee, or any other warm liquid.

  • It can also be used as wires which are used to locate and mark breast tumours so that following surgery can be more exact.

Platinum: The Magic Metal

PLATINUM, is more precious, and more enduring than gold. It is truly a magical metal.

HISTORY takes us back over 3000 years to ancient Egypt where the remarkable metalsmiths of that time became extremely skilled in the art of working with platinum. A 2500 year old coffin of an Egyptian High Priestess was discovered, decorated with platinum hieroglyphs. Their polish and luster were still perfect, giving dramatic proof of platinum's incomparable strength and durability.

Another ancient people who created adornments from platinum were the Incas. But the invading Spanish Conquistadors saw little use for the this metal, and deemed it "silver of lesser value", platina. They even went so far as to throw great amounts of the metal into the sea, thinking that it might become a cheap imitation for silver.

Finally, during the eighteenth century, platinum's value as a metal supremely suited for jewelry started to take hold. Then in the nineteenth century, platinum became the de-facto standard for setting the finest of the newly discovered gemstone, the diamond. In fact, the most famous of these gems, the Koh-I-Nor, the Jonker, and the Hope diamonds were all set in platinum.

CHARACTERISTICS
  • Platinum is the hardest of the precious metals, it never tarnishes. Its intense luster remains intact over the years, and it is completely hypoallergenic.
  • Platinum is extremely dense, and remarkably heavy. Much more so than silver or gold. This property of platinum enhances and ennobles the quality of the jewelry from which it is created.
  • The ultimate stability of platinum over the years is unmatched. It does not wear, and its extreme level of durability offers a profound guarantee of strength and longevity.
  • Platinum requires special skills and tools to work with.
  • Platinum has an extremely high melting temperature. In its purest form it melts at 3214 degrees F, almost twice the temperature needed to melt 14 karat gold.
  • All the platinum ever mined would produce a cube 17 feet on each side, less than 5000 cubic feet. 
  • It takes up to 10 tons of ore to produce one ounce of platinum, more than twice as much ore that is typically needed for an ounce of gold.
  • Platinum is not susceptible to problems like stress corrosion or stress cracking as can be the case with white gold.

Friday, March 19, 2010

Virtual Chemistry Experiments

Dear friends,
The below mentioned is a very good site for Virtual Chemistry Experiments:
http://www.chm.davidson.edu/vce/
Just visit on this site...
I am 100% sure that you will get some useful interactive material on basic Chemistry from this site.

Introduction

Hey dear friends,
I am here to discuss anything about chemistry what you know.....
I am here to share anything about chemistry what I know.....
You can post your queries on my email address and I will try to answer it asap.....