Diwali 2016: Festival of Light, Not Pollution

Diwali (Deepavali) is an Indian festival celebrated by lighting lamps, distributing sweets and bursting crackers. By tradition, homes are lit with clay lamps, candles, fairy lights, and firecrackers light the sky as people rejoice in the festival. Over the years, the bursting of fire crackers have reached high noise levels and air pollution during Diwali. Let us have a look at the various toxic chemicals, increasing levels of pollution and the methods to celebrate eco-friendly Diwali.

Chemicals in fireworks

Heavy smog hangs low in the air on Diwali night and a few days after that. The levels of sulphur nitrates, magnesium, nitrogen dioxide increase, and these chemicals are injurious to our respiratory passages. Diwali can be potentially fatal to asthamatics.

The various chemicals in fireworks and their effects -

Sulfur dioxide: Causes wheezing and shortness of breath.

Cadmium: Can cause anemia and damage to kidney and also affect the nervous system.

Copper: Irritates respiratory tract

Lead: Affects the nervous system

Magnesium: Can cause metal fume fever

Nitrate: Can cause mental impairment

Nitrite: Can cause skin problems, eye irritation, and respiratory problems in children.

Increasing pollution on Diwali

Unfortunately, every year, the quantum of air and noise pollution caused due to the bursting of firecrackers increases on Diwali. Firecrackers release pollutants such as sulphur dioxide, carbon dioxide, carbon monoxide etc in the air, which causes ailments like asthma and bronchitis. Last year, the air pollution levels had raised than any other years in past. The 2013 Diwali witnessed, the respirable suspended particulate matter (RSPM) levels at 236.2 microgram per cubic metre during Diwali; while the SOx (oxides of Sulphur) levels of 48.7 microgram per cubic meter during the festival. The NOx (oxides of Nitrogen) 35.3 microgram after the festival.

Celebrate eco-friendly Diwali

Lets us celebrate eco-friendly Diwali this year and save the environment from pollution. Diwali not only marks bursting cracker, but the glittering lights, boxes of sweets, freshly painted homes, exchange of gifts, family reunions. 
SAY NO TO CRACKERS

Read Full Story: Diwali 2016: Festival of Light, Not Pollution

Crab, shrimp shells useful for bone regeneration, drug delivery

TSUKUBA, JAPAN: A review of the latest research shows that combining a sugar, obtained from crab and shrimp shells, with a variety of nanomaterials could lead to the development of biomedical applications that enhance bone regeneration, wound healing and targeted drug delivery.

Properties of the nanocomposites are looked at for the bio medical and bio sensing applications.

Also the increasing need to develop green polymeric materials with improved thermal stability, gas barrier properties, strength and biodegradation, has led to the development of composite materials based on natural polymers.

The review, published in the journal Science and Technology of Advanced Materials, provides an overview of the different nanomaterials that are being tested in combination with chitosan, the methods used to prepare the composite materials and the resultant properties that make them suitable for applications in the biomedical field, reported ACN Newswire.

Chitosan is a sugar that is typically derived from shrimp and crab shell waste and is known for its biocompatible, biodegradable, antibacterial, antifungal, analgesic and haemostatic (stops bleeding) properties. This makes it an excellent candidate for a number of biomedical applications. Researchers are working on developing composites that combine chitosan with “nanofillers,” making the resulting material stronger.

Scientists are finding some success in combining bioactive glass nanoparticles with chitosan to develop synthetic bone grafts. Bioactive glass is a glass-ceramic biomaterial that binds well to physiological structures such as bone. Bone cells were found to grow relatively quickly and cover grafts made of bioactive glass and chitosan.

Graphene oxide has been used in combination with chitosan to develop “nanocarriers” that can deliver drugs to target tissues, avoiding the negative side effects that conventional drugs can have on other tissues of the body.

Silver nanoparticles are being tested as nanofillers in combination with chitosan to develop wound dressings with antibacterial properties.

Also, haemoglobin (the protein in red blood cells that carries oxygen through the body), silver nanoparticles and graphene have been combined with chitosan to develop a biosensor that can detect hydrogen peroxide, a dangerous by-product of some industrial processes.

Further research is needed. More focus is required on improving the dispersion of nanofillers within the chitosan matrix, according to the researchers. The vast opportunities shown by these materials, allied with their incredible nanotechnology potential, is expected to revolutionize the biomedical field in the near future.

Read Full Story: Crab, shrimp shells useful for bone regeneration, drug delivery

Chemistry of Teflon Cookware

In our day to day activity we are using lot varieties of cookware for preparing food and other purposes.

But…

Did you know some of our cookware that are specially coated with chemical coating i.e., Polytetrafluoroethylene (PTFE), coating?

This chemical name makes you think a lot? Never heard of this chemical?

What is it?

Let me give you the common name of Polytetrafluoroethylene i.e., “Teflon”

In this article I will give some of its characteristics, chemical nature, advantages, disadvantages etc…

Teflon is generally used for non-stick cookware. The non-stick cookware coating allows food to brown without sticking to the pan and this feature all because of Teflon. There are many misconceptions about teflon. Although it is used on armor-piercing rounds, it does not provide any of the armor-piercing capabilities. Teflon is solid with an extremely low coefficient of friction. The teflon coating is also used only to protect the rifling of the gun's barrel.

The metallic substrate is roughened to promote adhesion, and layers of PTFE, from one to seven, are sprayed or rolled on, with a larger number of layers and spraying being better. The number and thickness of the layers and quality of the material determine the quality of the non-stick coating.

Chemical characteristics of Teflon/ Polytetrafluoroethylene (PTFE)

Polytetrafluoroethylene is a synthetic fluoropolymer of tetrafluoroethylene that has numerous applications. It is a fluorocarbon solid, as it is a high-molecular-weight compound consisting wholly of carbon and fluorine. PTFE is hydrophobic in nature. It maintains high strength, toughness and self-lubrication at low temperatures down to 5 K (-268.15 °C; -450.67 °F), and good flexibility at temperatures above 194 K (-79 °C; -110 °F). PTFE was accidentally discovered in 1938 by Roy Plunkett while he was working in New Jersey for DuPont.

PTFE is used as a non-stick coating for pans and other cookware. It is very non-reactive, partly because of the strength of carbon–fluorine bonds, and so it is often used in containers and pipework for reactive and corrosive chemicals. PTFE also acts as lubricant and reduces friction, wear and energy consumption of machinery. It is commonly used as a graft material in surgical interventions. PTFE is used for applications where sliding action of parts is needed: plain bearings, gears, slide plates, etc. In these applications, it performs significantly better than nylon and acetal.

PTFE film is also widely used in the production of carbon fiber composites as well as fiberglass composites, notably in the aerospace industry. PTFE film is used as a barrier between the carbon or fiberglass part being built, and breather and bagging materials used to incapsulate the bondment when debulking and when curing the composite, usually in an autoclave. PTFE tubes are used in gas-gas heat exchangers in gas cleaning of waste incinerators.

PTFE is widely used as a thread seal tape in plumbing applications, largely replacing paste thread dope. PTFE-coated filters are often used in dust collection systems to collect particulate matter from air streams in applications involving high temperatures and high particulate loads such as coal-fired power plants, cement production and steel foundries.

PTFE can also be used for dental fillings, to isolate the contacts of the anterior tooth so the filling materials will not stick to the adjacent tooth. PTFE sheets are used in the production of butane hash oil due to its non-stick properties and resistance to non-polar solvents.

Side effects of teflon

The fumes released from non-stick cookware have been known to be highly toxic to birds, as many pet birds die from ‘Teflon toxicosis’ each year. When humans are exposed to the fumes they can experience a condition known as ‘polymer fume fever’. This is characterized by flu-like symptoms, including headaches, chills, fever, and coughing and chest tightness.

Read Full Story: Chemistry of Teflon Cookware

Role of Chlorine in Your Day to Day Life

Chlorine is the most abundant member of the halogen family of periodic table elements. Chlorine is an important chemical in our day-to-day life. Chlorine is a clear amber-colored liquid about 1.5 times heavier than water. Gaseous chlorine is greenish-yellow, about 2.5 times as heavier than air, which will cause it to initially remain near the ground in areas with little air movement. Chlorine has a pungent odor. Chlorine is a powerful oxidizing agent and it must be handled carefully. Chlorine is a yellow-green gas at room temperature.

Chlorine is a major building block for the chemical and pharmaceutical industry.Chlorine is also known as disinfectant in drinking water and in swimming pools, chlorine contributes to advances in areas as diverse as disinfecting, medicine, public safety and enhancing our everyday life.

Chlorine is not flammable, but may react explosively or form explosive compounds with many common substances (including acetylene, ether, turpentine, ammonia, natural gas, hydrogen, and finely divided metals).

 Chlorine is slightly water soluble, and reacts with moisture to form hypochlorous acid (HClO) and hydrochloric acid (HCl).

Chlorine is commonly pressurized and cooled for storage and shipment as an amber-colored liquid.

 Chlorine gas is a harmful poison, which was the first gas used in chemical warfare in World War I. It causes suffocation, constriction of the chest, tightness in the throat, and edema of the lungs. As little as 2.5 mg per litre in the atmosphere causes death in minutes, but less than 0.0001 percent by volume may be tolerated for several hours.

 Surprising sources of chlorine

 A Chinese folk medicine plant contains five natural organo chlorine compounds.

 An Ecuadorian tree frog produces a chlorinated alkaloid, with pain-killing properties several hundred times more powerful than morphine.

 A natural organ chlorine antibiotic i.e., vancomycin, is a key defense against hospital Staphylococcus infections.

 Some natural organ chlorinated products exhibit potent antibacterial and anticancer properties

 NASA’s Curiosity Rover, currently exploring the surface of Mars, has detected the presence of chlorine on the Red Planet. A Mars expert at the University of Michigan in Ann Arbor, US, stated that "the presence of perchlorates implies a source of chlorine, which was most likely derived from briny water or volcanic activity in the past".

 NASA also detected chlorinated methane compounds when soil samples were analyzed in Curiosity's on-board laboratory.

 Chlorine constitutes about 0.013 percent of the Earth's crust.

 Free chlorine has been reported as a very minor constituent of volcanic gases, of which hydrogen chloride (q.v.) is a fairly common component.

 Chlorine, as the chloride ion Cl-, is the main negative ion in ocean water (1.9 percent by weight) and in inland seas such as the Caspian Sea, the Dead Sea, and the Great Salt Lake of Utah

 It is found in evaporite minerals, for example, combined with sodium, as rock salt (halite) and in the minerals chlorapatite and sodalite.

 Natural chlorine is a mixture of two stable isotopes: chlorine-35 (75.53 percent) and chlorine-37 (24.47 percent).

 The Chloride ion is present in the body fluids of higher animals and as hydrochloric acid in the digestive secretions of the stomach.

 Properties

 Chlorine molecules are composed of two atoms (Cl2). Chlorine combines directly with almost all the elements to give chlorides

 Besides the -1 oxidation state of the chlorides, chlorine also exhibits +1, +3, +5, +7 oxidation states, respectively, in the following ions: hypochlorite, ClO-; chlorite, ClO-2 ; chlorate, ClO-3 and perchlorate, ClO-4 .

 Chlorine also exists in the forms of four oxides, such as chlorine monoxide (Cl2O), chlorine dioxide (ClO2), dichlorine hexoxide (Cl2O6), and dichlorine heptoxide (Cl2O7). All the four oxides are highly reactive and unstable, have been indirectly synthesized.

 Chlorine can displace the heavier halogens, bromine and iodine, from their ionic compounds and undergoes addition or substitution reactions with organic compounds. Chlorine enters directly or as an intermediate into the synthesis of many organic chemicals that are used as solvents, dyes, plastics, and synthetic rubber.

 Many chemicals, plastics and medicines depend on chlorine during the manufacturing process, although the chemical is not contained in the end product.

 Two third of all chlorine is used in the production of plastics, such as PVC, Poly-Urethanes, Epoxy-resins, Teflon, Neoprene etc., for use in construction, automotive, electronic and electrical industries.

 85 per cent of medicines, including many lifesaving drugs, are made using chlorine chemistry.

 25 per cent of medical devices contain chlorine, including blood bags, sterile tubing, heart catheters, prosthetics and X-ray films.

 More than 90 per cent of Western Europe's drinking water is made safe with the help of chlorine. Worldwide waterborne diseases kill 15 million people each year.

Chlorine production methods

Most chlorine is industrially produced by the electrolysis of brine. Chlorine is also obtained as a by-product in the manufacture of sodium metal by the electrolysis of molten sodium chloride.

One of the laboratory methods to prepare chlorine is reaction between sulfuric acid and sodium hypochlorite or hydrochloric acid with sodium hypochlorite. Sulfuric acid or hydrochloric acid reacts with sodium hypochlorite solution to release chlorine gas but reacts with sodium chlorate to produce chlorine gas and chlorine dioxide gas.

Industrial production of chlorine is through by following process

•  The membrane cell process
• The mercury cell process
• The diaphragm cell process

 Chlorine applications

 Chlorine and its compounds are used extensively for bleaching in the paper and textile industries, for disinfecting municipal water supplies, for household bleaches and germicides, and for the production of many organic and inorganic chemicals, in the separation of such metals as copper, lead, zinc, nickel, and gold from their ores.

 Chlorinated solvents are used as an extraction medium in pharmaceutical processes, in printing, mining and plastics processing, in the manufacture of adhesives and in paint & varnish remover

 Chlorine compounds have been used in pharmaceutical formulations for many years and play a part in the eradication of infection and disease. It is not only used in antiseptics, but in drugs such as chloramphenicol.

Read Full Story: Role of Chlorine in Your Day to Day Life

GST Implementation in India will Benefit Chemical Industries

Dr Joerg Strassburger, Founder and CEO, Go East Advisors GmbH shares his views with Chemical Today magazine on GST to be implemented in India. Before founding Go East, Dr Strassburger was the Country Representative and Managing Director of LANXESS India Pvt Ltd from 2005 to 2014.

That the government was finally able to win support for the GST legislation in the upper house of parliament and get all the amendments of the bill also passed in Lok Sabha is a big achievement for Prime Minister Modi. This important milestone of his plan to improve the “Ease of doing business” in India will not only simplify the way how to do business in India but it will also increase the competitiveness of the Indian economy.

Besides the direct positive impact in India it is also an important message to investors around the world that the government is still serious about the reform agenda. This I especially important as over the last months doubts were raised if the Modi government would be able to fulfil promises it made while taking office. With this achievement, the “Make in India” campaign also could get a new boost.

The chemical industry in India is one of the industries which will benefit most of the GST implementation as it is typically an industry which has few, capital intensive manufacturing locations and subsequently a lot of logistical activities which follow the actual production steps and which are necessary to reach the customers who are normally spread out all over India. A benefit for the whole economy and also for the chemical industry is, that if the GST set-up is done in an efficient way comparable to countries like Germany, it will also be avoided that cumulative cost effects influence the value chain and make production set-ups in India less competitive.

Even if the final design of the GST is not yet 100 percent decided it seems to be clear that for the chemical industry on a company level the positive effects of the GST introduction are significant. First of all, the internal efforts to manage the business and the work in the finance departments will be reduced as many of the numerous indirect taxes will be integrated into GST. In addition, GST linked to purchased products and services and GST charged to the customers can be counterbalanced which also results in internal processes becoming much easier.

But more importantly also direct savings can be realized. In today’s complex indirect tax legislation, a company, which for example produces chemicals in Gujarat and sells these products in Tamil Nadu tries to stay competitive by setting up a warehouse in Tamil Nadu to cater to the local customers. By doing a stock transfer from its production location to its sales warehouse the company will not only avoid the central sales tax and can thus price the products lower it will also be able to supply customers faster as it pre-pones the long transportation times which are due to multiple truck checking points.

But also, this kind of set-up is not for free for the company nor, eventually for the customer. The cost for setting up and running the local warehouse is not small and especially if a company is producing hazardous chemicals, suitable warehouse locations are sometimes difficult to find. In addition, the internal complexity to manage this kind of set-up for multiple locations requires expertise and manpower and thus stands for additional cost.

With introduction of GST the requirements for setting up warehouses in different Indian states will disappear for most chemical businesses in India. With the upcoming integration of CST into GST one of the major needs for the warehouse set up is not any longer existent. And depending on the final design of GST and as a result on how far finally the trucks will be able to circulate without being stopped also the just in time delivery will be possible over longer distances and so also this argument for local warehouses disappears.

In summary, it means that the introduction of a well-designed GST will be very beneficial for the chemical companies in India as the external and internal cost and the complexity of managing the numerous indirect taxes will be reduced and sales prices will be more attractive compared to imports. Knowing that chemical products often are intermediates to other chemicals this effect is cumulative and therefore the Indian chemical industry will be significantly more competitive after introduction of GST. This positive perspective might also help to reverse the trend seen in the last decade in many chemical segments that imports grew faster than local production.

Read More: GST Implementation in India will Benefit Chemical Industries 

20 Chemical Compounds found in Milk

Milk is a nutritious liquid that is secreted by mammals and used to feed their young, and as food by human beings. Worldwide, dairy farms produced about 730 million tonnes of milk in 2011.

Milk is a key contributor to improving nutrition and food security particularly in developing countries

The principal constituents of milk are

• Water
• Fat
• Proteins
• Lactose
• Minerals
• Pigments
• Enzymes
• Vitamins
• Phospholipids
• Gases

Milk seemingly white beverage may look innocent, but the hidden ingredients packed into the liquid. According to recent studies on milk, scientists have found single glass of milk can contain a mixture of as many as 20 painkillers, antibiotics and growth hormones etc.

These 20 compounds include

• Chloramphenicol
• Florfenicol
• Pyrimethamine
• Thiamphenicol
• Diclofenac
• Flunixin
• Ibuprofen
• Ketoprofen
• Naproxen
• Mefenamic acid
• Niflumic acid
• Phenylbutazone
• Triclosan
• Carbamazepine
• Clofibric acid
• β-blockers
• Metoprolol
• Propranolol
• 17α-Ethinylestradiol
• Estrone
• 17β-Estradiol

All cow's milk has 59 active hormones, countless allergens, lots of fat and cholesterol. Of those 59 mentioned hormones, one is a powerful growth hormone called Insulin- like Growth Factor ONE (IGF-1). This hormone is essentially a ‘fuel cell’ for any cancer. Furthermore these will promote and worsen all cancers, including those that are exists.

Solution to avoid effects from these type chemical compounds is the usage of organic milk. Organic milk is clearly better as organic dairy cows will not be given rBGH or routine antibiotics.

 One more simple solution is the usage of grass-fed raw milk.

Read More: 20 Chemical Compounds found in Milk

Interesting facts about nitrogen element | Nitrogen Prevents Oxidation of Food

Nitrogen is a chemical element and it can be represented as N and atomic number of 7. In normal conditions nitrogen is a colorless, odorless and tasteless gas. Nitrogen makes up around 78 per cent in our surrounding atmosphere. Nitrogen is one of the primary nutrients critical for the survival of all living organisms. Although nitrogen is very abundant in the atmosphere, it is largely inaccessible in elemental form to most organisms.

Nitrogen is also present in other forms. When people think of nitrogen, they immediately associate it with the air in the environment. Nitrogen not only part of atmosphere but also part of the food they eat every day. Since its discovery, scientists have learned a lot about it and today with technology development nitrogen is commercially available in large amounts, various forms. The most common types are nitrous oxide and super coolant liquid nitrogen. Nitrous oxide is one of the nitrogen compound commonly known as laughing gas.

Liquid nitrogen is nitrogen in a liquid state at an extremely low temperature. It is produced industrially by fractional distillation of liquid air. Liquid nitrogen is a colorless clear liquid. Liquid nitrogen is a compact and readily transported source of nitrogen gas without pressurization. Liquid nitrogen has also become popular in the preparation of cocktails because it can be used to quickly chill glasses or freeze ingredients.

Liquid nitrogen can be applied for freezing and transport of food products, cryopreservation of biological samples, and coolant for superconductors, vacuum pumps, also used in cryotherapy to remove skin abnormalities, shielding materials from oxygen exposure, cooling materials for easier machining or fracturing.

This element is the lightest in the nitrogen group. Nitrogen can join up with other elements. The bonds are very effective because nitrogen’s outermost electron shell has few electrons. That is the reason why it is sometimes used as a buffer gas. Nitrogen is present as one of the building blocks or constituent of amino acids, proteins, nucleic acids, chlorophyll and other biomolecules.

Nitrogen is one of the primary nutrients critical for the survival of all living organisms. Although nitrogen is very abundant in the atmosphere as dinitrogen gas (N2), it is largely inaccessible in this form to most organisms, making nitrogen a scarce resource and often limiting primary productivity in many ecosystems. Only when nitrogen is converted from dinitrogen gas into ammonia (NH3) does it become available to primary producers, such as plants.

Nitrogen is a fascinating element with many unique properties and uses related to fertilizer, dynamite, medical anesthetic and even car racing. Read interesting facts about the nitrogen atom, liquid nitrogen, nitrous oxide, nitric acid, nitroglycerin and much more.

Nitrogen is present in all living things, including the human body and plants. Nitrogen gas is used in food storage to keep packaged or bulk foods fresh. It is also used in the making of electronic parts, for industrial purposes and has many other useful applications. Nitrogen gas is often used as an alternative to carbon dioxide for storing beer in pressurized kegs.

Titan, the largest moon of Saturn, has an atmosphere nearly entirely made of nitrogen. It is the only moon in our solar system known to have a dense atmosphere. Nitrogen is in a liquid state when at a very low temperature. Liquid nitrogen boils at 77 kelvin (−196 °C, −321 °F). It is easily transported and has many useful applications including storing items at cold temperatures, in the field of cryogenics, as a computer coolant, removing warts and much more.

Nitrogen role in health care and diseases

Decompression sickness involves nitrogen bubbles forming in the bloodstream and other important areas of the body when people depressurize too quickly from scuba diving. Similar situations can occur for astronauts and those working in unpressurized aircraft. Nitrous oxide (N2O) is used in hospitals and dental clinics as an anesthetic. Nitrous oxide is also used in motor racing to increase the power of engine and speed of the vehicle. Nitrous oxide is a considerable greenhouse gas and air pollutant. By weight is has nearly 300 times more impact than carbon dioxide.

Nitroglycerin is a liquid used to create explosives such as dynamite. It is often used in the demolition and construction industries as well as by the military. Nitric acid (HNO3) is a strong acid often used in the production of fertilizers. Ammonia (NH3) is another nitrogen compound commonly used in fertilizers.

Rainfall adds about 10 pounds of nitrogen to the soil per acre per year. The nitrogen oxides and ammonium that are washed to earth are formed during electrical storms, by internal combustion engines and through oxidation by sunlight. Some scientists also believe that some of the gaseous products that result from the transformation of nitrogen fertilizers may cause a depletion of the ozone (O3) layer around the earth. The extent of this possible damage has not been substantiated.

Crop residues decompose in the soil to form soil organic matter. This organic matter contains about 5 percent nitrogen. An acre-foot of soil having 2 percent organic matter would contain about 3,500 pounds of nitrogen. Generally, about 1 to 3 percent of this organic nitrogen is converted per year by microorganisms to a form of nitrogen that plants can use.

Commercial fertilizer nitrogen comes in three basic forms

Gaseous nitrogen
Liquid nitrogen
Dry nitrogen
All forms are equally effective when properly applied. Once applied, fertilizer nitrogen is subject to the same transformations as other sources of nitrogen.

Nitrogen Transformations

Nitrogen exists in a number of chemical forms and undergoes chemical and biological reactions.

Organic nitrogen to ammonium nitrogen

Organic nitrogen comprises over 95 percent of the nitrogen found in soil. This form of nitrogen cannot be used by plants but is gradually transformed by soil microorganisms to ammonium (NH4+). Ammonium is not leached to a great extent. Since NH4+ is a positively charged ion, it is attracted to and held by the negatively charged soil clay. Ammonium is available to plants.

Ammonium nitrogen to nitrate nitrogen (nitrification)

In warm, well-drained soil, ammonium transforms rapidly to nitrate (NO3-). Nitrate is the principle form of nitrogen used by plants. It leaches easily, since it is a negatively charged ion (anion) and is not attracted to soil clay. The nitrate form of nitrogen is a major concern in pollution.

Nitrate or ammonium nitrogen to organic nitrogen (immobilization)

Soil microorganisms use nitrate and ammonium nitrogen when decomposing plant residues. The addition of 20 to 70 pounds of nitrogen per ton of these residues is needed to prevent this transformation. After the residues are decomposed, the microbial population begins to die back and processes 1 and 2 take place.

Nitrate nitrogen to gaseous nitrogen (denitrification)

When soil does not have sufficient air, microorganisms use the oxygen from NO3- in place of that in the air and rapidly convert NO3- to nitrogen oxide and nitrogen gases (N2). These gases escape to the atmosphere and are not available to plants. This transformation can occur within two or three days in poorly aerated soil and can result in large loses of nitrate-type fertilizers.

Ammonium nitrogen to ammonia gas (ammonia volatilization)

Soils that have a high pH can lose large amounts of NH4+ by conversion to NH3 gas. To minimize these losses, incorporate solid ammonium-type fertilizers, urea and anhydrous ammonia below the surface of a moist soil.

Applications of nitrogen

This element is present in virtually all pharmacological drugs. In the form of nitrous oxide it is used as an anesthetic. Cryopreservation also uses the gas to conserve egg, blood, sperm and other biological specimens. The CPUs in computers use the gas to keep them from heating up. X-ray detectors also rely on this element.

The element is used in controlling pollution. It is effective in getting rid of unstable organic compounds in liquids. Many industries use it to destroy toxic liquids and vapors in industrial tools. As nitrogen dioxide, the element is vital in the industrial sector. It also serves as an oxidation reaction catalyst. Apart from being an oxidizing agent, it can also be used as a flour bleaching agent and rocket fuel.

It has found several uses in the industrial sector, of which a few important uses are explained below.

Light Bulbs

Nitrogen is often used in making light bulbs. It serves as an inexpensive substitute for argon in incandescent light bulbs.

Packaged Foods

Nitrogen is used to preserve the freshness of packaged foods. Nitrogen can prevent the oxidation of food, and thus delay rancidity and other forms of oxidative damage.

Fertilizers

Nitrogen is one of the most important ingredients in fertilizers, to increase soil fertility. It is used to make other fertilizers like ammonia and urea, which are used to promote plant growth and increase yield.

Reactive compounds production

 It can produce a range of unstable and highly reactive compounds, like nitrogen triiodide, ammonium nitrate, trinitrotoluene (TNT), nitric acid, and nitroglycerin.

Electronic Parts

Nitrogen is used for making transistors, integrated circuits, and diodes.

Stainless Steel

Nitrogen is often used in manufacturing stainless steel, electroplating processes in order to make it stronger and more resistant to corrosion.

High Voltage Equipment

Dried and pressurized nitrogen gas is used as a dielectric gas for high voltage equipment. Nitrogen is also used as a pressurizing gas to propel liquids through pipelines.

Nitrogen is also used for pollution control, especially for eliminating volatile organic compounds from liquids. It can help remove harmful vapors and liquids from industrial equipment as well.

Pharmaceuticals

Nitrogen is a constituent of almost every major class of drugs, including antibiotics. In the form of nitrous oxide, nitrogen is used as a pharmaceutical anesthetic agent.
Read More: Interesting facts about nitrogen element | Nitrogen Prevents Oxidation of Food