LATEST:- Electronic Materials Tough It Out

Makers of electronic chemicals remain committed to innovation despite hard times

Seventeen years in the electronic materials industry have taught Corning F. Painter this lesson: An electronic materials supplier that cuts down on R&D commits corporate suicide. "One way to drop out is to discontinue research," says the Taipei-based head of global electronics at Air Products & Chemicals. "Two to three years later, you're not positioned for what comes up."

Like those in other business sectors, companies supplying materials to electronic components manufacturers have had an exceptionally difficult time in the past eight months. Because of the steep decline in demand for electronic chemicals, producers are struggling to maintain profitability by dramatically cutting production. Yet amid the global economic downturn, the pace of new product development hasn't slowed, with electronic materials suppliers preserving, and even strengthening, their R&D capabilities.

For example, Nobu Koshiba, president of Japan's JSR Corp., can't conceive of drastically cutting back on R&D spending, even though the company's sales of electronic materials will likely shrink considerably. "I need to readjust our fixed costs to reflect the reduced size of our sales," he says. "So I will cut back into some of our excess production capacity, but I won't sacrifice our future by cutting R&D." JSR is, in fact, expanding its materials R&D programs into new markets such as lithium capacitors, where the company has no sales yet, Koshiba points out.

The magnitude of the drop in business over the past six months is stunning. At JSR, which provides dielectrics, photoresists, optical films, and other materials to both the semiconductor and the flat-panel-display industries, business in the first three months of 2009 was down about 40% from a year ago, Koshiba says.

For the whole of 2009, Koshiba foresees that demand for electronic materials could be down 30% compared with 2007, which was an exceptionally good year. Putting things into a historical context, Koshiba says the current downturn is about as bad as what the electronics industry went through in 2001 after the burst of the dot-com bubble.

"Until August last year, business was so strong we didn't know where to get our raw materials," says Karl-Rudolf Kurtz, a group vice president who heads BASF's global electronic materials business. BASF's range of electronic materials includes pure chemicals and chemical planarization slurries used in the semiconductor industry, display materials such as optical films, and chemicals used in solar cell manufacturing. "Then suddenly business almost stopped in October," he recalls. One of the few things Kurtz could do when the crisis started was cut down production in order not to accumulate excess inventory.

If it's any consolation, companies have better information systems to manage production and inventories during this downturn than they did in 2001. At Air Products, for example, once Painter realized last autumn that demand had fallen off a cliff, he asked for a list of products in Air Products' inventory that have a limited shelf life and received it in one day. "In the past, this would have taken maybe a month of manual labor to track down," he says. "We have better tools to manage the downturn."

Most electronic chemicals go into three major markets: semiconductors, display panels, and solar energy cells. Each business has long had its own dynamic, which has held through the economic downturn.

The semiconductor industry is the most sophisticated segment, requiring the most advanced materials. It's also the one in the most trouble. A recovery to the level of sales in 2007 could take as long as five years, JSR's Koshiba says. Yet he acknowledges that his dire recovery scenario could be too pessimistic. Historically, the personal computer market has been the chief barometer for the semiconductor industry, he explains. But today, integrated circuits are in a wide range of applications, including cars and telephones. "Semiconductors could become less cyclical," he says.

In the flat-panel-display segment, first-quarter demand for televisions, computer screens, and mobile phones was so weak that producers had to cut capacity utilization of manufacturing facilities to only 60%, says David Hsieh, vice president for Greater China at the market consulting firm DisplaySearch. Since April, however, demand has strengthened to last year's level. "For the remainder of this year, we are sort of optimistic for panel demand, as well as for the materials suppliers," he says.

Among these suppliers is Merck KGaA, the world's leading producer of liquid crystals for liquid-crystal displays (LCDs), the most common screen. After a sharp drop late last year and early in 2009, sales of liquid crystals are now slowly climbing back to the level they were at in the first half of 2008, says Roman Maisch, Merck's vice president of liquid-crystal marketing and sales. Sales in euros or dollars remain down somewhat, however, because of reduced pricing.

Moreover, much of the demand is for "standard mixtures" of liquid crystals used to build 32-inch LCDs, Maisch says. The display industry had believed that consumers were eager to buy the largest possible displays, but Maisch notes that they tend to be satisfied with medium-sized screens. Consumers in China, where demand is particularly robust, mostly buy 32-inch LCD TVs.

China has been key to the recovery of the display segment in the past few months. Strong demand there is due to an economic stimulus package that is boosting consumer demand for television sets. In June, Air Liquide said it would spend $35 million to build air separation plants in southwest China that will supply new facilities producing LCDs for televisions. The French firm noted that Chinese production capacity for LCD TVs is increasing at nearly 30% annually.

In contrast to the recession-induced slump in demand for display and semiconductor materials, demand for solar materials such as polysilicon, protective films, and specialty gases has remained strong through the economic downturn. This is particularly true in Asia where, according to BASF's Kurtz, most solar energy projects that have been announced are still going ahead.

The buoyant solar energy market is still not large enough, however, to rescue electronic materials producers, Painter says. Despite its rapid growth, the market for solar energy materials remains smaller than that for semiconductor or display materials. The standout material is polysilicon, which is now used more by the solar energy industry than by semiconductor makers. Moreover, because the materials used to generate solar energy can be less pure than those required by the semiconductor and display industries, profit margins are lower, Kurtz says.

"Until August last year, business was so strong we didn't know where to get our raw materials."

Even as demand from these three markets stalls, the electronics industry continues to launch an increasing variety of devices that require a broader range of materials than ever. In fact, today's iPhones, BlackBerry Smartphones, and MP3 players can boast as much computing firepower as a two-year-old laptop or PC. The next-generation models are going to be even more powerful.

"The ecosystem of microelectronics has expanded," says Geoff Irvine, vice president of business development at SAFC Hitech, the performance materials arm of Sigma-Aldrich. The chips that go into mobile phones are different from those used to make desktop computers, he explains. At the same time, old chip designs now remain in production long after newer and higher performing ones have entered the marketplace. Materials suppliers therefore must support multiple product generations.

Despite the downturn, Irvine says, SAFC's customers have intensified their R&D into the numerous types of chips that manufacturers of consumer goods demand. One of the major trends, he notes, is the rise of electronic devices that are smaller, consume less power, and emit less heat. These new requirements affect manufacturing processes and the types of materials being used. "We're seeing an acceleration of R&D," he says, and SAFC has responded by hiring more researchers of its own.

In the electronics industry, SAFC is a supplier of semiconductor materials with particular expertise in design and supply of materials used for thin film deposition processes. The company also participates in the solar industry, where it serves manufacturers of thin film and solar cells.

The same intensifying trend in chip R&D is supporting demand for certain chemicals from Air Products. Chip manufacturers are constantly trying to cram more memory onto one piece of silicon by making circuitry smaller, Painter says. Air Products is experiencing good demand for its LTN and LTO lines of silicon nitride and silicon oxide precursor molecules, which can be deposited at lower temperatures, thus reducing the risk of damaging fragile circuits during the manufacturing process. Demand for these product lines has been good despite the downturn, according to Painter. "We've raced to ramp up production to meet global demand, even in the downturn," he says.

Electronic materials suppliers always endeavor to support semiconductor companies' efforts to shrink chip circuitry. Kurtz says BASF recently launched a new type of chemical planarization slurry, used to polish chips during manufacture. Polishing can damage chips, and BASF's new silica-free "adaptive organic" slurries contain "smart" particles designed to deliver just the right amount of chemical components to the wafer, the company says. This reduces the danger posed by excessive polishing.

It is also becoming particularly hard to develop circuit wire insulating materials that meet the semiconductor industry's needs. These materials, known as low-k dielectrics, have a small dielectric constant compared with silicon dioxide, the traditional insulator. "We should really use something like air, but it's not that easy to handle," Kurtz says. It may seem odd, but according to BASF, air is the "ultimate" low-k material, as long as it can be controlled effectively.

Air Products has found a way to handle air, according to Painter, with a dielectric system it calls pDEMS, for porous diethoxymethylsilane. It allows chip makers to apply a low-k film featuring pores filled with air. Some semiconductor plants producing advanced generations of chips are using the material, Painter says.

In February, JSR announced a research collaboration with IBM to develop new materials for the next generation of microcircuits. For example, the companies are seeking a material that combines the functions of a low-k dielectric and a photoresist—used to imprint circuitry on semiconductors by means of photolithography. Combining the two functions into a single material will reduce waste and simplify manufacturing, the partners say.

Innovation continues in display technology as well, because even though economically constrained consumers are sticking to the basics, such as modest-sized TV sets, others still look for high-end goods. Merck's sales head Maisch says it's been surprising to see how quickly manufacturers of flat displays have adopted Merck's new liquid-crystal technology, dubbed Polymer Stabilized-Vertical Alignment.

Displays based on the new materials promise high contrast and fast switching, properties that reduce the amount of power required for backlighting. The liquid-crystal materials can be used in television sets, mobile phones, and portable gaming devices. "There is strong demand for our latest technology," which Merck has been developing in close collaboration with customers since 2006, Maisch says.

Reducing the amount of power that an LCD consumes is a major goal among flat-panel-display manufacturers. One approach uses a light-emitting diode (LED) as the backlight source instead of standard cold-cathode fluorescent light (CCFL), DisplaySearch's Hsieh says. LED backlights are "the most influential technical change under way now" at panel manufacturers, he says.

The switch to LED backlighting involves a whole range of new materials, Hsieh says, in particular because LED light is not as strong as CCFL and LED lighting works only with the help of brightness enhancement filters. Because only a handful of materials manufacturers have the know-how to make brightness enhancement films, Hsieh says, the panel industry has been experiencing shortages in the past six months.

At Fujifilm, meanwhile, business managers are thinking beyond simple improvements in backlighting. Earlier this year, the company said it had developed two new films that could lead to breakthroughs in flexible displays, electronic paper, solar cells, and flat light sources.

Traditionally a producer of photographic films, Fujifilm has recently emerged as a world leader in the development of films used in LCDs. It manufactures films that widen display-viewing angles. And it is the world's largest producer of cellulose triacetate films used in LCD polarizers. In the fiscal year that ended March 31, however, the company suffered a sharp drop in demand for its display films as a result of the global recession.

One of Fujifilm's new display films has extremely high moisture barrier properties. Covering a display panel with a strong barrier against air and moisture is essential to maintaining device performance and ensuring durability. So far, glass is the only transparent material with the necessary properties, says Katsuo Nakadai, senior engineering manager for Fujifilm's industrial products division.

"No such material has been available in the past, therefore manufacturers have been developing devices on the assumption that such a material would not exist," Nakadai says. How much of a blockbuster the new material will be for Fujifilm remains unclear because the company's customers are still only testing samples. But Nakadai expects the film will find wide use among producers of organic LEDs, electronic paper, and even flexible solar cells that could be fitted on the body of a car.

Fujifilm's customers are also assessing the other new film, branded Exclear. Making use of technology Fujifilm originally developed for black-and-white photography, the transparent film is made of polyethylene terephthalate coated with a light-sensitive silver halide. Intended as a conductive material for touch-panel displays, the film can replace indium tin oxide, which cracks and breaks over time.

"We're hoping for 100% adoption by customers," Nakadai says. "We don't think that adoption will slow during the downturn because the film is the material that panel makers had hoped for." Because of its properties, Exclear can also be used in flat light sources. By 2013, the market for the film could be worth more $400 million, Fujifilm predicts.

It took Fujifilm several years to develop the new films, a length of time that is not unusual in the electronic materials industry. From time to time, however, material makers come up with innovation much faster.

For example, as a direct result of the global economic downturn, Air Products came up with a xenon-recovery system for use inside semiconductor plants, where the noble gas is used in a number of processes. According to Painter, the global supply of xenon has tightened sharply since the economic downturn began, thereby making recycling the rare gas imperative.

Xenon is extracted from air by air separation plants designed mainly to supply oxygen, nitrogen, and argon, Painter explains. Because it represents just a small fraction of the air, xenon can be economically captured only at large separation plants that are typically set up at steel mills, he says. And when steel production went down with the rest of the economy, xenon availability fell as well.

Air Products' Xecovery system allows semiconductor fabricators to recycle a portion of the xenon they use. "The industry is looking for cost control, and the recycling of xenon is a great cost control," Painter says. "It's not like you can go out and make more xenon." Semiconductor producers are now testing the technology.

That the economic downturn spurred innovation among makers of electronic materials is par for the course in an industry where innovation is a way of life. Among managers of electronic materials companies, there is probably no one who believes that cutting R&D is a good way to raise profits. In fact it's quite the opposite. "Only new products, new materials," BASF's Kurtz says, "will get us out."

Chemical & Engineering News

ISSN 0009-2347

Copyright © 2009 American Chemical Society

LATEST:- ChemLogix Selected In 2009 Supply & Demand Chain Executive 100

MEDIA, PA, July 01, 2009 /Chemical News Articles/ -- According to the magazine, ChemLogix' inclusion in this year's "100" list recognizes the company's leadership as a solution and service provider in assisting the supply chain function and supply chain executives as their customers position their organizations not only to meet the urgent business imperatives of the current downturn but also to thrive as the economy rebounds.

"We are honored to have been recognized by Supply & Demand Chain Executive for successfully enabling our customers to build economic value during these challenging conditions. Our close customer relationships have been critical for us to be proactive in driving cost and process improvements," states Steve Hamilton, President & CEO of ChemLogix.

Eight years ago, Supply & Demand Chain Executive announced its first "100" list of supply chain solution providers, consultants and other organizations that were helping lead the way in transforming companies' supply and demand chains. This year, the magazine focused the criteria for its "100" feature on economic recovery. Final recipients are featured in the cover story of the June/July 2009 issue of Supply & Demand Chain Executive, as well as online at www.SDCExec.com/SDCE100.

"Our goal with this year's '100' is to highlight a broad range of solutions and services targeted at a variety of industries, addressing the needs of companies of varying sizes, and assisting in the transformation of a diverse mix of the functions that make up the supply chain," explained Andrew K. Reese, editor of Supply & Demand Chain Executive.

For more information about ChemLogix, go to www.chemlogix.com or contact Ken Vrtis at kvrtis@chemlogix.com or 630-579-8200.

LATEST:- SODIUM

History

(English, soda; Medieval Latin, sodanum: a headache remedy) Long recognized in compounds, sodium was first isolated by Davy in 1807 by electrolysis of caustic soda.

Sources

Sodium is present in fair abundance in the sun and stars. The D lines of sodium are among the most prominent in the solar spectrum. Sodium is the fourth most abundant element on earth, comprising about 2.6% of the earth's crust; it is the most abundant of the alkali group of metals.

It is now obtained commercially by the electrolysis of absolutely dry fused sodium chloride. This method is much cheaper than that of electrolyzing sodium hydroxide, as was used several years ago.

Compounds

The most common compound is sodium chloride (table salt), but it occurs in many other minerals, such as soda niter, cryolite, amphibole, zeolite, etc.

Properties

Sodium, like every reactive element, is never found free in nature. Sodium is a soft, bright, silvery metal which floats on water. Decomposition in water results in the evolution of hydrogen and the formation of the hydroxide. It may or may not ignite spontaneously on water, depending on the amount of oxide and metal exposed to the water. It normally does not ignite in air at temperatures below 115oC.

Uses

Metallic sodium is vital in the manufacture of esters and in the preparation of organic compounds. The metal may be used to improve the structure of certain alloys, descale metal, and purify molten metals.

An alloy of sodium with potassium, NaK, is an important heat transfer agent.

Compounds

Sodium compounds are important to the paper, glass, soap, textile, petroleum, chemical, and metal industries. Soap is generally a sodium salt of certain fatty acids. The importance of common salt to animal nutrition has been recognized since prehistoric times.

Among the many compounds that are of the greatest industrial importance are common salt (NaCl), soda ash (Na2CO3), baking soda (NaHCO3), caustic soda (NaOH), Chile saltpeter (NaNO3), di- and tri-sodium phosphates, sodium thiosulfate (hypo, Na2S2O3 . 5H2O), and borax (Na2B4O7 . 10H2O).

Isotopes

Thirteen isotopes of sodium are recognized.

Cost

Metallic sodium is priced at about 15 to 20 cents/lb in quantity. Reagent grade (ACS) sodium in January 1990 cost about $35/lb. On a volume basis, it is the cheapest of all metals.

Handling

Sodium metal should be handled with great care. It cannot be maintained in an inert atmosphere and contact with water and other substances with which sodium reacts should be avoided.

LATEST:- MEILIAN CHEMICAL INDUSTRY

Meilian Chemical is a manufacturer specialized in PE-based masterbatch. With 8 state-of-the-art masterbatch production lines, it has a capacity of 20000 tons per year. Located in the beautiful seashore city – Shantou, the facilities cover a land of 20 thousand square meters.

Meilian Chemical currently focuses on four ranges of PE masterbatch comprising black, white color and additive masterbatch, which are for use in a wide range of film, molding, tubing, sheet applications, and much more.

Meilian Chemical is growing into a leading Chinese masterbatch producers and exporters. Competitive price, consistent quality and commitment to outstanding service make Meilian Chemical a preferred partner for its customers home and abroad. Domestic buyers are mainly from the South, the East and the North of China, which are relatively developed industrial areas. On the international market, it has business partners from Europe, North America, South America, Africa, Oceania, Southeast Asia and the Middle East.

Meilian Chemical has membership in the Masterbatch Committee of China’s Dyestuff Industry Association and has been a major supporting unit for the Annual Convention organized by the Committee for consecutive years. Registered with the China Council for the Promotion of International Trade (CCPIT), it is accessible to the service of CCPIT.

Based on the industry know-how and the ability to identify customer needs, in addition to striving for excellence in the field of masterbatch, Meilian Chemical has been experiencing in the service of coloration and modification of a broad range of copolymers for its domestic and international customers.

Commitment to ensuring consistent quality and enhancing management efficiency remains one of the most important criteria of the company’s success. Meilian Chemical is striving for sustainable development together with its extensive customers by playing a key role in their success, and is dedicated to contributing to the growth of the plastic industry.

LATEST:- Chemical Society Cutbacks

Global economic downturn necessitates job and benefit cuts at world's largest scientific society

William G. Schulz

Investment losses, declining ad revenues, and falling institutional print subscriptions to its journals and other publications have forced the American Chemical Society to cut 3% of its workforce and make further reductions to operating expenses and retiree medical benefits. The cost-saving measures were announced on April 28.

Linda Wang/C&EN

The American Chemical Society's headquarters in Washington, D.C.

"We were looking for a total package of savings that, in light of the global economic downturn, would help us achieve the goals laid out in our 2009 budget and continue to operate in the black," says ACS Executive Director and CEO Madeleine Jacobs. In addition to job cuts, the society has capped certain retirement health benefits and reduced general expenses across all operating units. "The cuts were strategic, they were not evenly distributed," Jacobs says.

The society's Publications Division took the biggest hit in job cuts. Of a total of 56 ACS employees who were laid off, 40 worked in the ACS Publications Division, including nine members of the C&EN staff and 10 members of C&EN's Journal News & Community Department.

ACS Publications Division Director Brian Crawford says two driving factors were behind the division's cuts: declining ad revenues for C&EN, especially classified job advertising, and cancellation of print subscriptions to ACS journals by institutional subscribers. The switch from print to electronic versions of ACS journals has happened at a much faster pace than anticipated, he says, resulting in a revenue loss.

Nonetheless, Jacobs and Crawford both stress the fundamental financial health of ACS and its revenue-generating units, which include Chemical Abstracts Service, ACS Publications, and Membership & Scientific Advancement. Jacobs notes that although ACS saw the value of its unrestricted reserves fall starting in late 2008, from about $212 million to about $60 million, the society is liquid, with nearly $275 million in cash and investments. She says declines in the capital markets and ACS's obligation to fund its pension benefits led to the dramatic drop in reserves that occurred. By freezing accruals in the society's defined-benefit pension plan and by capping retiree health insurance, she says, ACS has been able to restrain the decline in reserves.

The cuts are "geared to the long term," Crawford says. He notes that the Publications Division remains at the forefront of scientific publishing operations that are gradually shifting to all or mostly electronic formats and that the shifts entail some pain. But "I anticipate that the actions taken will suffice for the remainder of the year and should position the Publications Division for the next three years," he says.

"The staff reductions we made were painful but necessary," C&EN Editor-in-Chief Rudy Baum says. "I remain committed to producing a high-quality, weekly newsmagazine in print and electronic formats that informs ACS members and other readers of important news, events, and trends in the chemical enterprise in a timely, accurate, and balanced fashion. That remains C&EN's mission, and we will continue to fulfill it."

New stylings from Ciba provide wide array of

June 08, 2009 - "XYMARA™ Fireball™ stylings bring characteristics of color and color shift that are not to be found elsewhere," said Tom Landuydt, Global Marketing Head of Automotive Coatings at Ciba. "The transparency, warmth and sparkle of Fireball™, when combined in new recipes, have resulted in a series of unique shades."The new stylings – Melting Magma, Sunset Marina, Treasure Grove, Burning Amber, Spicy Velvet and Bloomy Vapor – make use of high-end technology that gives high durability, making them suitable for demanding application areas such as exterior automotive coatings and other high-performance items, including mobile phones, personal digital assistants and laptops.When used alone, XYMARA™ Fireball™ gives a unique color-travel effect, varying from orange/gold to a deep cherry red, depending on the angle of observation. Its inherent transparency makes it ideal for combination with other transparent pigments as well as in multilayer paint systems. The new stylings are not only versatile in terms of color, but also in their compatibility with different paint systems – they can be used for both waterborne and solventborne applications, allowing maximum flexibility in formulation.A brochure, available free of charge, describes and illustrates the new stylings as well as providing technical information on how to achieve them.For a detailed description of the new XYMARA™ Fireball™ stylings, please visit www.xymara.com.About Ciba Inc.Ciba (SWX: CIBN), part of BASF since April 2009, is a leading global company dedicated to producing high-value effects for its customers’ products. We strive to be the partner of choice for our customers, offering them innovative products and one-stop expert service. We create effects that improve the quality of life – adding performance, protection, color and strength to plastics, paper, automobiles, buildings, home and personal care products and much more. Ciba is active in more than 120 countries around the world and is committed to be a leader in its chosen markets. In 2008, the Company’s continued operations generated sales of CHF 5.9 billion and invested more than CHF 230 million in R&D.For further information please contact:Ciba Investor Relations:Tel. +41 61 636 5084Fax +41 61 636 5111Ciba Media:Tel. +41 61 636 4444Fax +41 61 636 3019

LATEST CHEMICAL NEWS

UK carbon capture and storage gets government boost

24 April 2009

The UK will lead the way in the development and use of carbon capture and storage technology for coal-fired power stations, the country's minister for energy and climate change has declared.

Talking to the House of Commons on 23 April, Ed Miliband announced that any company seeking planning approval for new coal-fired power stations would have to commit to retrofitting carbon capture and storage (CCS) across the whole plant once the technology is available. In the same speech he also outlined plans to develop this technology using the extra funding for CCS research announced in the UK's 2009 budget.

Miliband acknowledged that coal - renowned as a more polluting fossil fuel than gas - will continue to play an important part of the UK's energy provision, but reiterated that 'there is an urgent international imperative for us to make coal clean'. He went on to propose two new conditions that any companies wanting to build new coal-powered power stations must meet in order to gain consent in England and Wales: CCS should be demonstrated on at least 300MW of any new coal-fired power station's capacity (approximately a quarter of a standard sized plant's output), and that the company must also agree to fit CCS on the entire plant once the technology is proven.

Technically and economically

During his budget speech on 22 April, Alistair Darling, the UK's chancellor of the exchequer, pledged 'a new funding mechanism to support up to four CCS demonstration projects, and £90 million to fund detailed preparatory studies'. The UK previously had plans to run just one of these demonstration projects, as part of a European Commission strategy to encourage around 12 full-scale CCS demonstration projects by 2015. A competition has been ongoing since 2007 to decide which company would run this trial, with the winner expected to be announced in mid-2009. Three contenders remain in the race: E.ON UK, Peel Power, and Scottish Power. There is no word yet how, or if, this week's news will affect the competition's outcome.

Miliband has now added more details to Darling's plan, saying that the new demonstrations would 'be a mix of pre- and post-combustion' and would be clustered in regions where they can achieve the greatest emission reductions the most economically, such as Thames, Humberside, Teesside, Firth of Forth and Merseyside. He also suggested this might herald a new future for the North Sea oil and gas industry, capitalising on an abundance of offshore storage sites for CO₂. 'This route is right, too, for the British economy, and will enable us to lead the world in carbon capture and storage,' he added. 'Research suggests that carbon abatement technologies could sustain 50 000 jobs by 2030.'

Lukewarm response

Green energy experts have cautiously welcomed Miliband's comments. Stuart Haszeldine, from the Scottish centre for carbon storage at the University of Edinburgh, said that 'this is a big step towards accelerating routine decarbonisation of electricity from 2020, and total decarbonisation by 2030, as recommended by the [UK government's] climate change committee. Building new coal-fired power plants without operational carbon capture and a connection to a transport and storage cluster, now becomes unjustifiable.'

Some researchers, however, are concerned about the detail in Miliband's statement. '[This] announcement on the CCS scheme has the feel of sleepwalking into oblivion. The fact that there are now apparently four demonstration plants is new but the sizes and timescales lack so greatly in definition that it provides the government with the maximum opportunity to dither for a very long time,' said Miles Seaman from the Institution of Chemical Engineers.

Others have voiced concerns that the funding mechanism has not yet been thought through. Jon Gibbins, from the Energy technology for sustainable development group at Imperial College London, said 'this is good news, but to make anything happen there has to be an effective way of recovering the costs of any CCS projects. Otherwise it's no new coal and no CCS.

Ammonium nitrate

The chemical compound ammonium nitrate, the nitrate of ammonia with the chemical formula NH₄NO₃, is a white crystalline solid at room temperature and standard pressure. It is commonly used in agriculture as a high-nitrogen fertilizer, and it has also been used as an oxidizing agent in explosives, including improvised explosive devices.

Ammonium nitrate is used in cold packs, as hydrating the salt is an endothermic process.

Production

The processes involved in the production of ammonium nitrate in industry, although chemically simple, are technologically challenging. The acid-base reaction of ammonia with nitric acid gives a solution of ammonium nitrate:^[3] HNO₃(aq) + NH₃(g) → NH₄NO₃(aq). For industrial production, this is done using anhydrous ammonia gas and concentrated nitric acid. This reaction is violent and very exothermic. After the solution is formed, typically at about 83% concentration, the excess water is evaporated to an ammonium nitrate (AN) content of 95% to 99.9% concentration (AN melt), depending on grade. The AN melt is then made into "prills" or small beads in a spray tower, or into granules by spraying and tumbling in a rotating drum. The prills or granules may be further dried, cooled, and then coated to prevent caking. These prills or granules are the typical AN products in commerce.

The Haber process combines nitrogen and hydrogen to produce ammonia, part of which can be oxidised to nitric acid and combined with the remaining ammonia to produce the nitrate. Another production method is used in the so-called Odda process.

Sodium

Sodium (pronounced /ˈsoʊdiəm/) is an element which has the symbol Na (Latin natrium, from Arabic natrun), atomic number 11, atomic mass 23 [g/mol], and a common oxidation number +1. Sodium is a soft, silvery white, highly reactive element and is a member of the alkali metals within "group 1" (formerly known as ‘group IA’). It has only one stable isotope, ²³Na. Sodium was first isolated by Sir Humphry Davy in 1806 by passing an electric current through molten sodium hydroxide. Sodium quickly oxidizes in air and is violently reactive with water, so it must be stored in an inert medium, such as kerosene or mineral oil. Sodium is present in great quantities in the Earth's oceans as sodium chloride (common salt). It is also a component of many minerals, and it is an essential element for animal life. As such, it is classified as a “dietary inorganic macro-mineral.”

Chemical properties

Compared with other alkali metals, sodium is generally less reactive than potassium and more reactive than lithium,^[2] in accordance with "periodic law": for example, their reaction in water, chlorine gas, etc.;

Sodium reacts exothermically with water: small pea-sized pieces will bounce across the surface of the water until they are consumed by it, whereas large pieces will explode. While sodium reacts with water at room temperature, the sodium piece melts with the heat of the reaction to form a sphere, if the reacting sodium piece is large enough. The reaction with water produces very caustic sodium hydroxide (lye) and highly flammable hydrogen gas. These are extreme hazards (see Precautions section below). When burned in air, sodium forms sodium peroxide Na₂O₂, or with limited oxygen, the oxide Na₂O (unlike lithium, the nitride is not formed). If burned in oxygen under pressure, sodium superoxide NaO₂ will be produced. In chemistry, most sodium compounds are considered soluble but nature provides examples of many insoluble sodium compounds such as the feldspars. There are other insoluble sodium salts such as sodium bismuthate NaBiO₃, sodium octamolybdate Na₂Mo₈O₂₅• 4H₂O, sodium thioplatinate Na₄Pt₃S₆, sodium uranate Na₂UO₄. Sodium meta-antimonate's 2NaSbO₃•7H₂O solubility is 0.3g/L as is the pyro form Na₂H₂Sb₂O₇• H₂O of this salt. Sodium metaphosphate NaPO₃ has a soluble and an insoluble form

Toxic Chemicals Are Destroying Our Health - an Interview With Debra Lynn Dadd

(NaturalNews) Panelist for The International Health and Fitness Symposium and "The Queen of Green," Debra Lynn Dadd, Talks with Symposium Chairman and Host Craig Pepin-Donat, The Fit Advocate, about Toxic Chemicals that are Destroying our Health.

The World Cancer Report states that cancer rates could increase by 50%, to 15 million new cases, by the year 2020. Cancer rates are higher amongst industrial nations, with the United States amongst the top five, according to the World Health Organization. In spite of advances in science and technology, toxic exposure from the environment, chemicals in our food, water supply, personal hygiene products, and household cleaning products contribute to our nation's ill health.

Debra Lynn Dadd, renowned author and the "Queen of Green," was one of 12 top experts in the fields of health, fitness and nutrition, who participated in The International Health and Fitness Symposium, hosted by author and international fitness expert Craig Pepin-Donat, The Fit Advocate. The Symposium brings together, in one composition called The People's Guide to Health, Happiness and Longevity, what it would take the average person years to research and discover.

In this ground-breaking segment from The People's Guide to Health, Happiness and Longevity, Dadd speaks with Craig Pepin-Donat about the startling health risks created by toxic chemicals in everyday cleaning products. You can learn more about Debra Lynn Dadd at (www.thepeoplesguidetohealth.com/The...) .

Toxins in Our Homes

Craig Pepin Donat: With toxins all around us, making us sick, what products should we avoid? What should we be concerned with that could damage our health?

Debra Lynn Dadd: Virtually any product that is in your home may have toxic chemicals in it, because there are toxic chemicals in every type of product. If you are not currently attempting to buy non-toxic products, then you probably have hundreds of toxic chemicals in your home. You might find particleboard furniture that emits formaldehyde, and chemicals in synthetic wall-to-wall carpet, a wood stove, and a fireplace. In the kitchen, aluminum cookware, canned food, and cleaning products may contain toxic chemicals. Coffee and chocolate may contain very dangerous pesticides. Now, as I point to this list, I don't want you to think that you can never drink coffee or you can never eat chocolate. You can. You just need to buy organic products. You don't have to be 100 % nontoxic all the time. You need to avoid enough chemicals so that your body can naturally regenerate itself and naturally heal itself, so that your immune system can work properly.

When you're in a nontoxic environment, your body detoxes. If you go into a toxic environment, you put toxic chemicals back into your body. One of the benefits of having a non-toxic home is that all the hours that you're in your house, your body is detoxing. Then, if you go out in the world and you're exposed to something, your body's much stronger.

Toxins in our Body

Pepin-Donat: How do these chemicals get into our bodies in the first place?

Dadd: There are four ways chemicals come into your body. You can ingest them; they can get absorbed through your skin; you can inhale them, because they're floating around in the air, and, they can get splashed into your eyes. Those are the only four roots of exposure, but there are many ways that your body tries to get rid of them. A lot of symptoms that we think of as just being common symptoms, that we might take an over-the-counter drug for, are actually symptoms of your body trying to get rid of something toxic.

Those symptoms would include: sweating, vomiting, diarrhea, excessive urination, mucus membrane secretions. How many times do we suppress those symptoms when our body's trying to cleanse itself?
If you can't get toxins out of your body, your body starts collecting them in your fat tissue, in your bones, in your cell membranes, and in various other organs. You can end up with all kinds of illnesses, including cancer and heart disease. Your endocrine system also gets affected by toxic chemicals and that affects every area of your body. It affects fertility, reproduction, sex drive; you could be depressed. A lot of people who are exposed to toxic chemicals end up having hypothyroidism, because the thyroid gland is very sensitive to toxic chemicals. It affects your ability to lose weight or gain weight or maintain a regular weight.

Our bodies have a tremendous ability to heal and regenerate themselves. When we're sick, we think that illness is something wrong with our body. What illness means is that something is right with our body; it's our body trying to correct the problems. We just need to let the symptoms do their job, and you'll come out well in the end. Don't try to suppress them.

Living "Green"

Pepin-Donat: I think people are afraid of "going green," in their homes. First, you have to research all these products, and then find alternatives. They are afraid it may be difficult, or costly. But that's not true, is it, Debra?

Dadd: Let's talk about cleaning products for a minute, because cleaning products are one of the most toxic products you're going to find in your home, and they're also one of the easiest to change.

Everybody can wash their windows with vinegar and water. You can get rid of ammonia. If you look on cleaning products, a lot of them have warning labels that say "Caution" or "Danger." Find the ones that have the skull and crossbones on it, and those are the ones you cannot use anymore.

Most people are sleeping on sheets and bed linens that are saturated with formaldehyde. Formaldehyde causes insomnia. You have people all over the country buying millions of dollars worth of sleeping pills; all they need to do is change their sheets. You could get rid of a lot of toxic chemicals, our world would be perfectly fine, and we'd still be able to do everything we're doing. It's just a process of learning a different way.

CHEMICAL INDUSTRIES

The Chemical Industries Association (CIA) is the organisation that represents chemical and pharmaceutical businesses throughout the UK.

Our activities are split between lobbying and provision of advice and services. Our policy agenda stretches across the economy and competitiveness; our products and the way we work; health, safety & environment and employment issues.

The products and services of the chemical and pharmaceutical industry can be found in every area of our lives – from vital medicines, foods and clothing, through housing and transport, to communications and leisure activities. Our industry, which underpins so much of society’s needs and wants, is also a significant provider of jobs and creator of wealth for the UK.

All our companies are committed to achieving sustainable development. Playing a key role in this is the Responsible Care programme which requires that companies continuously improve their performance related to the safety of their sites, the health of their employees when at work and the impact of their operations on the environment. Our partnership with chemical and pharmaceutical businesses forms policy at industry level and ensures standards at company level.

We hope that you find our website helpful, please let us know what you think. Contact us: enquiries@cia.org.uk or call 020 7834 3399

The Chemical industry is an industry that matters...

DIXIE CHEMICAL COMPANY, INC.

Specialty Chemical Manufacturer

Dixie Chemical Company is a recognized leader in the manufacture and marketing of high-purity specialty and pharmaceutical intermediates.

Dixie's services include: Providing technical and end-use market information for its unique and extensive product line. Manufacturing the molecule of your choice, under contract, with complete confidentiality. Assisting you in the development process by providing laboratory support and project engineering from kilogram to multi-ton quantities.

Dixie's manufacturing facilities are situated on approximately 60 acres in the Bayport Industrial Area 25 miles southeast of Houston. Research and Development facilities, quality control labs and a modern pilot plant capable of supporting most unit processes are located near the production units. Dixie is a member of the American Chemical Council (ACC) and the Synthetic Organic Chemical Manufacturers Association (SOCMA) and has implemented all aspects of the Responsible Care® Code.

AVM CHEMICALS

The group of technical people from populous; formed a partnership firm, “Pakistan Chemical Corporation (PCC)” in Karachi. The objective of founding the firm was to become a leading manufacturers and exporter of sodium silicate. PCC works till 1979 and the business shattered due to sad demise. Haji Abdul Ghaffar (late) was one of the partner of Pakistan Chemical Corporation (PCC) with a super technical excels. Afterward, Haji Abdul Ghaffar (late), start his new own business work with his technical capabilities by the name of “Abbo Vali Mohammad - (AVM Enterprise)” in the field of business.

From the establishment, 1979, AVM Enterprise is working in the field of chemical trading. It has major dealings in Sodium Silicate and other Textile Auxiliaries, Dyes and Chemicals.

NEELIKON CHEMICALS

ISO 9001:2000 Certified, Govt. recognized in-house R & D unit, manufacturers of food colours, pharmaceutical colours, cosmetic colours, US FDA Certified FD&C and D&C colors, aluminum lakes, salt free dyes for pens, pyranine for highlighters and fluorescent dyes used for resin-pigment manufacturing & other specialized applications.

PRODUCT NAME	: NEELIGLOW YELLOW 172
COLOUR INDEX NAME	: SOLVENT YELLOW 172
CHEMICAL CLASS	: COUMARIN
HUE	: FLUORESCENT GREENISH YELLOW
FORM SUPPLIED	: POWDER
APPEARANCE	: YELLOWISH ORANGE
MELTING POINT	: 298ºC - 303ºC
lmax	: 447 - 448 nm (DMF)
SOLUBILITY	: VERY LOW SOLUBILITY IN MOST POWERFUL SOLVENTS
USAGE	: SUITABLE FOR SURFACE COATINGS AND LACQUERS. RESIN PIGMENTS FOR PRINTING INKS AND PAINTS

Kiri Dyes and Chemicals Limited

One of the foremost manufacturers and suppliers of high quality dyes and intermediates in the dyestuff industry. Through innovation, dedication to total quality and consumer satisfaction, as well as commitment to research and development, we have succeeded in meeting the needs of a broad range of customers worldwide.

KDC production facilities are strategically located in the heart of chemical industrial zone, which provides comparative ease and convenience to effectively utilize the Common Effluent Treatment Plant to further treat outlets. Centralized administration is established in highly commercial area of the city, Ahmedabad.

RIA DYES AND CHEMICALS

Profile
Ria Dyes manufacture and export a wide range of quality dyestuffs to different parts of the world. The company has been successful in retaining confidence of its clients consistently due to its focus on maintenance of quality driven by its quality-centered policies and systems, which are monitored religiously.

Products
A wide range of high quality Reactive Dyes, Acid Dyes and Direct Dyes, spanning wide spectrum of application industries is the pillar of strength of the company: Product range includes :

• Reactive Dyes
  -- 'COLD' Dyes, HOT Dyes, HE Dyes, Bifunctional Dyes, VS Dyes
• Acid Dyes
  -- Acid Dyes, Acid Milling Dyes, Acid Metal Complex Dyes
• Direct Dyes
  -- A wide range of Sunfast & Non-Benzidine Direct Dyes

Quality

RIA DYES AND CHEMICALS

Profile
Ria Dyes manufacture and export a wide range of quality dyestuffs to different parts of the world. The company has been successful in retaining confidence of its clients consistently due to its focus on maintenance of quality driven by its quality-centered policies and systems, which are monitored religiously.

Products
A wide range of high quality Reactive Dyes, Acid Dyes and Direct Dyes, spanning wide spectrum of application industries is the pillar of strength of the company: Product range includes :

• Reactive Dyes
  -- 'COLD' Dyes, HOT Dyes, HE Dyes, Bifunctional Dyes, VS Dyes
• Acid Dyes
  -- Acid Dyes, Acid Milling Dyes, Acid Metal Complex Dyes
• Direct Dyes
  -- A wide range of Sunfast & Non-Benzidine Direct Dyes

Quality

SPECTRUM CHEMICALS

"We manufacture and distribute fine chemicals and laboratory products - with quality and delivery you can count on every time."

If you work in an analytical, research or development laboratory, Spectrum has the laboratory fine chemicals you require. Produced and packaged under strict quality guidelines, Spectrum’s product offering of over 12,000 fine chemicals is one of the largest in the industry.

Whether you are in charge of a pilot plant, small production facility or several large facilities, your bulk chemical requirements are the same. You want a reliable source for bulk chemicals that offers the right grade of material for your process with quality and delivery you can count on every time.

Spectrum is your One-Stop-Solution for laboratory equipment, laboratory supplies & laboratory safety items. We distribute nearly 80,000 laboratory equipment, supply and safety items from over 200 manufacturers like Sartorius, Microflex, Mettler Toledo, Nalge/Nunc, Denver Instruments, Julabo, Corning, Jencons, IKA, Caframo,Dyn-A-Med, Hanna, Kimble, ThermoFisher and LabChem to name a few.

DAWOOD HERCULES CHEMICALS

An interview with the GM Plant Of Dawood Hercules Chemicals
Mr Aslam has been associated with Dawood Hercules for more than 36 years. Born in Lahore, he graduated in Chemical Engineering in 1969 from the Punjab University and served there as a lecturer for one year. He joined Dawood Hercules in January 1971 as an assistant engineer while the plant was being erected. He has worked in several key positions through out his career and was eventually appointed as GM in May 2005. His hobbies include cricket and home workshop where he assembles, designs and repairs various articles

DESCON CHEMICLAS

Road To Descon Chemicals

Founded in 1980, Descon Chemicals has established itself as one of the leading Chemical Manufacturer in the country. Descon Chemicals offers its clients and partners a diverse portfolio of products, unsurpassed quality and technical service, strong commitment and innovation driven by latest trends in the market. All these ingredients result in Descon Chemicals helping its clients to add value to their products and production process, which are driven by introducing new ideas and solutions.
During 1980 a production facility engaged in the manufacturing of Sulphuric Acid was acquired by DESCON which after restructuring and reorganising was renamed as “Salfa Chemicals”. With the birth of “Salfa” Descon entered into the chemical sector in Pakistan.
In 1982 “Delta Industries (Pvt) Ltd.” which was adjacent to “Salfa Chemicals” was acquired by Descon and later on Salfa Chemicals was merged into Delta Industries. After the merger, Delta Industries initiated an aggressive development and growth plans. Delta made significant investments in R&D and infrastructure and with continuous hard work, introduction of innovative products, the organization evolved into a major player in the chemical sector. Delta increased it’s product range by many folds and became a major producer of POLYMER products covering Water Based Coating Resins, Alkyd Resins, Amino Resins, Hard Resins and Special Resins, Unsaturated Polyester Resins and Special Coating Additives. Delta’s Product Line also included Textile Chemicals and Paper Chemicals.
During 2004, with an objective to align the name of the Company with its actual line of business, Delta Industries Pvt. Ltd. was renamed as Dawchem Industries (Pvt) Ltd.
During 2006, as a result of Corporate Strategy and futuristic thinking of Descon management, Dawchem Industries Pvt. Ltd. was finally re-named as DESCON CHEMICALS (PVT) LTD

ENGRO CHEMICALS

It all started in a small town of upper Sindh province

From Esso to Engro
Search for oil by Pak Stanvac, an Esso/Mobil joint venture in 1957, led to the discovery
of Mari gas field situated near Daharki -- a small town in upper Sindh province. Esso
was the first to study this development in detail and propose the establishment of a urea
plant in that area.

The proposal was approved by the government in 1964, which led to a fertilizer plant agreement signed in December that year. Subsequently in 1965, the Esso Pakistan Fertilizer Company Limited was incorporated, with 75% of the shares owned by Esso and 25% by the general public. The construction of a urea plant commenced at Daharki the following year with the annual capacity of 173,000 tons and production commenced in 1968. At US $ 43 million, it was the single largest foreign investment by an MNC in the country.

A full-fledged marketing organization was established which undertook agronomic programs to educate the farmers of Pakistan. As the nation’s first fertilizer brand, Engro (then Esso) helped modernize traditional farming practices to boost farm yields, directly impacting the quality of life not only for farmers and their families, but for the community at large. As a result of these efforts, consumption of fertilizers increased in Pakistan, paving the way for the Company’s branded urea called "Engro", an acronym for "Energy for Growth".

As part of an international name change program, Esso became Exxon in 1978 and the company was renamed Exxon Chemical Pakistan Limited. The company continued to prosper as it relentlessly pursued productivity gains and strived to attain professional excellence.

In 1991, Exxon decided to divest its fertilizer business on a global basis. The employees of Exxon Chemical Pakistan Limited, in partnership with leading international and local financial institutions bought out Exxon’s 75 percent equity. This was at the time and perhaps still is the most successful employee buy-out in the corporate history of Pakistan. Renamed as Engro Chemical Pakistan Limited, the Company has gone from strength to strength, reflected in its consistent financial performance, growth of the core fertilizer business and diversification into other fields.

Investment in people, process solutions and resource conservation initiatives have reduced energy use per ton of urea by a third, whilst increasing urea production nearly six-fold since 1968. Not only does this save money, it stretches non-renewable energy sources and mitigates the impact of waste. Along the way, a major milestone in plant capacity upgrade coincided with the employee led buy-out; innovatively optimizing our resources, Engro re-located fertilizer manufacturing plants from the UK and US to its Daharki plant site – an international first. Our pioneering spirit continues in our social investments, exemplified by the only snake-bite treatment facility in the Ghotki region and the first telemedicine intervention in the country.