commercializing the triple bond
TRANSCRIPT
RESEARCH
At Air Reduction Chemical's lab in Murray Hill, N. J., continuous acetylene reactions are studied in the prepilot plant. Above, a general purpose reactor and other equipment are mounted on a pipe scaffold in a large bay in the center of the lab building
pentynol, a hypnotic, and methyl buty-nol.
Versatility of the glycols is rather striking. Dimethyl hexynediol and dimethyl oxtynediol have surface-active properties. They also have antigelling effects in media containing polyvinyl alcohol, act as pigment dispersion stabilizers in water-based systems, reduce viscosity in inks and in vinyl plas-tisols, and have corrosion-inhibiting properties. In addition, dimethyl octy-nediol is a fair light stabilizer in liquid vinyls.
Longer chain acetylenic alcohols and diols are currently being evaluated for developmental scale production. Surface activity of some of these materials is so strong that they are being introduced as a new class of nonionic surface-active agents. Use of the diols in synthetic resins and in a number of other syntheses is another promising development. Intensive development work is now being done on several derivatives of the acetylenic alcohols and glycols, including saturated diols and isopropenylacetylene, produced by dehydrating methylbutynol.
The bulk of this research and development work is being done in Airco's laboratory at Murray Hill, N. J. Built in 1947, the building originally housed research and development staffs on mechanical, metallurgical, and chemical problems. With the decision to increase emphasis on chemical research, mechanical development facilities were relocated at Union, N. J., and the additional space converted to chemical use. Chemical research staff now numbers
Commercializing the Triple Bond A concentrated research effort at Air Reduction
Chemical hopes to bring about commercial development of a large ly untapped f ield, acetylenic compound
A BASIC POSITION IN ACETYLENE a n d ***• more than 20 years experience in its chemical applications are being parlayed, by means of concentrated research effort, into commercial development of a largely untapped field of chemistry: that of acetylenic compounds. Air Reduction Chemical Co. was formed for this purpose a little over two years ago, when research work at the parent Air Reduction Co. indicated the soundest basis for rapid and profitable expansion was a core of organic-chemical-producing facilities to serve as a starting point for new, volume-chemical products.
Chemical research had been maintained by Air Reduction for a number
of years, but it had been aimed entirely at processes rather than products. Over the past two years the research staff has been greatly enlarged t o allow emphasis to be placed on new products. Several promising siew-comers have already advanced to large-scale pilot production, with many encre in all stages of research and development.
First products to reach commercial development were a group of tertiary acetylenic alcohols and glycols, deirivecl by the addition of a ketone to acetylene. Dimethyl hexynediol is used as a starting material in the synthesis ocf the insecticide allethrin. Stabilizers for chlorinated hydrocarbons are methyl
Acetylene generator house has a "weak wall" on the side away from the main lab, about a hundred yards distant. At left are four hopper-fed generators; at right a battery of filters
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RESEARCH
Both oxygen and nitrogen are trailer-truck delivered and can be piped directly from the above station throughout lab building. One tank in building is scale-mounted to record amounts used
Reaction temperature is checked in prepilot plant, glass-lined reactor. Production processes are developed here in Murray Hill, then moved to Bound Brook for drum quantity production
over 100, of whom 651 r are classified pi; as professional.
The background of the laboratory is reflected in some of its features. Acetylene, oxygen, nitrogen, and air are piped throughout the building and are available at the laboratory benches. Liquid oxygen is delivered by tank truck and stored in several large Dewar-type tanks. One oxygen tank, inside the building, is scale-mounted so the amount removed for direct use in pilot experiments can be directly determined. Acetylene is produced from calcium carbide in a special building about a hundred yards from the lab and piped underground directly to the benches. The acetylene generator house has a "weak wall" facing away from the main building.
Gas, water, and other services in the large central organic laboratory are located on service strips, which divide the room into four bays. Furniture and racks are thus independent of the services, lending flexibility to the arrangement. All permanent facilities, such as exhaust hoods, are located on three sides of the room. Double aluminum apparatus racks, unitized and independent of the furniture, are separated by 3/8-inch sheets of transparent meth-acrylate. These safety shields lessen the possibility of injury without blocking light.
Product development laboratories are hard at work on finding applications for derivatives turned out by research. Production processes are developed in the prepilot plant at Murray Hill, then moved to Airco's full size pilot plant at Bound Brook, N. J., where chemicals are produced in drum quantities. When the market warrants further expansion, a site for a multimillion pound
kmt is available at Calvert City, Ky., where a new National Carbide acetylene plant (largest in the U. S., capacity 300,000 tons of carbide a year) assures an adequate raw material supply- So far, this budding chemical
Perfect Iron Crystals Produced; Are Strong and Resistant to Rust
Perfect crystals of pure iron have been produced by GE. The crystals-whiskers about 0.001 inch thick and an inch or so in length—are said to be stronger than any previously known metal or alloy and may attain a tensile strength of nearly 1 million pounds per square inch. They are also inherently resistant to rust.
The perfect crystals are the first examples of metals as strong as theory predicts, according to C. G. Suits, GE vice president and director of research. Iron crystals previously made were thought to be nearly perfect but actually had irregularities on the atomic scale. These defects cause weakness and are the reason ordinary metals have a strength of at least 100 times less than the theoretical value. Although the crystals are of no practical use they may shed light on the strength of metals and alloys.
These crystals—produced by R. L. Pullman and Arno Gatti—are different from "passive iron/ ' Passivity is due to formation on the metal of a film which resists oxidation. In GE's new crystals, the perfection of the sides of the crystal would be expected to make them less likely to oxidize, and GE is now trying to determine how far this is actually the case.
company is not making tank car quantities of any of its products but is concentrating on developing the commercial aspects of a relatively unknown but potentially promising field of chemistry.
First observations of the whiskers were made at Bell Telephone Labs. Telephone relays under test failed mysteriously; research showed that whiskers of tin had grown and caused a short circuit.
Suits, speaking on a forum 'Tomorrow and Science," in connection with the centennial of Omaha, Neb., said the crystals "provide a new and exciting dimension in metallurgy."
A perfect crystal of pure iron is shown between an ordinary pinhead ( left ) and a micromanipulator. Strength of the crystals is calculated from the amount of bending they withstand when moved by the manipulator
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V O L U M E 3 2, N O . 1 5 » . . . A P R I L 1 2 , 1 9 5 4 1467
. . . a structural uni t
Glucuronic Acid is an important basic structural unit of the mucopolysaccharides present in essentially all fibrous and connective tissues. In blood and urine of both animals and humans, it occurs in conjugation with steroids and other physiologically active substances.
Highly purified, stable forms of Glucuronic Acid are now available commercially — crystalline GLUCURONOLACTONE, SODIUM GLUCURONATE, POTASS I U M G L U C U R O N A T E , and CALCIUM GLUCURONATE. All four compounds are soluble in water and may be used in a variety of reactions for the preparation of interesting new pharmaceutical products.
Requests for samples and technical information will receive prompt attention.
RESEARCH _ _
High-Purify Gal l ium Prepared By Single Crysta l Growth
High-purity gallium has been produced at the Naval Research Laboratory by a modification of the Kryopoulos technique of zone purification and single crystal growth. The merJbod is thought to be simpler and faster than various chemical means that could have been used.
Since gallium melts at 29.7° C, a simple water bath held as 38° C was all that was required to keep th^ gal-hum molten. A silica container was used to hold the gallium.
Single crystals were grown with a minimum effort; samples were taken from tops and tips of all crystals. After two cycles of crystal growth, there were only five elements that comld b e detected spectrographically as.impurities; eight others had been reduced s o that they were no longer detectable. All the impurities had been recluced by a minimum factor of 10 and some by a factor of more than 1000. Total impurity content of the second crop was not more than 0.005% and probably nearer to 0.001. Continued growth could probably bring further purification by at least one factor of 10.
NRL's W. Zimmerman, III, reports his findings in March 26 issme of Science.
SRI Says Research Needs Louder Voice in Industrial Planning
Research executives must be given more consideration in industry's long-range planning, says J. E. Hobson, director of Stanford Research Institute. In the introduction to SRI's 1953 report, Hobson points out that industry, realizing that applied research goals must be compatible with the company's financial capabilities, market conditions, and techno-economic trends, is giving more attention to research thinking. "Research executives are moving u p into the policy-making stratum of the corporate hierarchy," he says.
More than 340 research clients used SRI's services in 1953, placing 382 separate studies. SRI itself sponsored 39. Volume for the year was over $5.4 million, 19% greater than in 1952.
The year also saw expansions In staff and facilities: $380,000 was expended for new equipment and leasehold improvements; staff expanded 30*%, reaching an all-time high of 674.
Calcium Stripped of 14 Electrons Identified in Sun
Calcium stripped of 14 electrons has been identified in a spectrogram, made of the sun's rim on Feb. 2, 1950. Finding poses new problems for astro
physicists; they will have to revise upwards their calculations of heat and energy potentials of the sun or its solar flares.
Identification of the calcium as the cause of a previously unidentified yellow fine in the sun's corona has been unexplained since it was first discovered 16 years ago. Since the line is not found routinely in spectrograms of the corona, some astrophysicists believe it occurs in solar flares, the bursts of energy from the sun's surface. Stripped calcium atoms have not been produced in the laboratory, although it is possible they could be by some of the larger accelerators.
Findings were made by W. O. Roberts, D. E. Billings, and Charlotte Pecker of the coronographic station of the High Altitude Observatory at Climax, Colo. Research was sponsored by Office of Naval Research.
• Erythromycin is more effective against amebias is than any other agent so far developed, according to Hamilton Anderson and associates at the Univeristy of California school of medicine (San Francisco) and Sonoma State Hospital (Eldridge). Children suffering from this common chronic intestinal infection were treated; erythromycin was more effective than fuma-gillin, the most potent previous agent, the researchers say in March issue of American Journal of Tropical Medicine and Hygiene.
• Research on reducing stream pollution from spent sulfite liquor made excellent progress in 1953, according to annual report of Sulphite Pulp Manufacturers' Research League. During the year, practical mill-scale operation proved techniques are now available which substantially reduce undesirable conditions in streams below most mills, but whether they will prove economical has not yet been established. Fifteen mills in the league have expended over $10 million for pollution-control, and report estimates another $15 million is needed before the job will be completed.
• University of Vermont and S t a t · Agricultural College receives two grants from Research Corp.: $7000 to be used towards purchase of an infrared spectrometer and to support Richard G. Inskeep's investigations in infrared spectroscopy; $2800 to permit Clinton D. Cook to continue his investigations of sterically hindered phenols. Cook's grant will enable him to obtain an ultraviolet spectrometer.
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