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Sunday, January 19, 2020

BASF

From Wikipedia, the free encyclopedia
 
Societas Europaea
Traded asFWBBAS
DAX Component
ISINDE000BASF111 Edit this on Wikidata
IndustryChemicals
Founded6 April 1865; 154 years ago (as Badische Anilin und Soda Fabrik); Mannheim, Baden
FounderFriedrich Engelhorn Edit this on Wikidata
HeadquartersLudwigshafen, Germany
Key people
Jürgen Hambrecht (Chairman of the supervisory board), Martin Brudermüller (CEO and Chairman of the executive board)
ProductsChemicals, plastics, performance chemicals, catalysts, coatings, crop technology, crude oil and natural gas exploration and production
RevenueIncrease 62.675 billion (2018)
Decrease €6.033 billion (2018)
Decrease €4.707 billion (2018)
Total assetsIncrease €86.556 billion (end 2018)
Total equityIncrease €36.109 billion (end 2018)
Number of employees
Increase 122,404 (end 2018)
Websitebasf.com

BASF SE is a Germany-based European chemical company and the largest chemical producer in the world. The BASF Group comprises subsidiaries and joint ventures in more than 80 countries and operates six integrated production sites and 390 other production sites in Europe, Asia, Australia, the Americas and Africa. Its headquarters is located in Ludwigshafen, Germany. BASF has customers in over 190 countries and supplies products to a wide variety of industries. Despite its size and global presence, BASF has received relatively little public attention since it abandoned manufacturing and selling BASF-branded consumer electronics products in the 1990s.

At the end of 2017, the company employed around 115,490 people, with over 52,000 in Germany. In 2015, BASF posted sales of €70.4 billion and income from operations before special items of about €6.7 billion. The company is currently expanding its international activities with a particular focus on Asia. Between 1990 and 2005, the company invested €5.6 billion in Asia, for example in sites near Nanjing and Shanghai, China and Mangalore, India.

BASF is listed on the Frankfurt Stock Exchange, London Stock Exchange, and Zurich Stock Exchange. The company delisted its ADR from the New York Stock Exchange in September 2007. The company is a component of the Euro Stoxx 50 stock market index.

History

BASF Werk in Ludwigshafen, 1865
 
BASF is an initialism for Badische Anilin und Soda Fabrik (German for 'Baden Aniline and Soda Factory'). It was founded by Friedrich Engelhorn on 6 April 1865 in Mannheim, in the German-speaking country of Baden. Engelhorn had been responsible for setting up a gasworks and street lighting for the town council in 1861. The gasworks produced tar as a byproduct, and Engelhorn used this for the production of dyes. BASF was set up in 1865 to produce other chemicals necessary for dye production, notably soda and acids. The plant, however, was erected on the other side of the Rhine river at Ludwigshafen, because the town council of Mannheim was afraid that the air pollution from the chemical plant could bother the inhabitants of the town. In 1866, the dye production processes were also moved to the BASF site.

Dyes

BASF Werk in Ludwigshafen, 1881
 
The discovery in 1857 by William Henry Perkin that aniline could be used to make intense colouring agents had led to the commercial production of synthetic dyes in England from aniline extracted from coal tar. BASF recruited Heinrich Caro, a German chemist with experience of the dyestuffs industry in England, to be the first head of research. Caro developed a synthesis for alizarin (a natural pigment in madder), and applied for a British patent on 25 June 1869. Coincidentally, Perkin applied for a virtually identical patent on 26 June 1869, and the two companies came to a mutual commercial agreement about the process.

Further patents were granted for the synthesis of methylene blue and eosin, and in 1880, research began to try to find a synthetic process for indigo dye, though this was not successfully brought to the market until 1897. In 1901, some 80% of the BASF production was dyestuffs.

Soda

BASF main laboratory in Ludwigshafen, 1887
 
Sodium carbonate (soda) was produced by the Leblanc process until 1880 when the much cheaper Solvay process became available. BASF ceased to make its own and bought it from the Solvay company thereafter.

Sulfuric acid

Indigo production at BASF in 1890
 
Sulfuric acid was initially produced by the lead chamber process, but in 1890, a unit using the contact process was brought on stream, producing the acid at higher concentration (98% instead of 80%) and a lower cost. This development followed extensive research and development by Rudolf Knietsch, for which he received the Liebig Medal in 1904.

Ammonia

The development of the Haber process from 1908 to 1912 made it possible to synthesize ammonia (a major industrial chemical as the primary source of nitrogen), and, after acquiring exclusive rights to the process, in 1913 BASF started a new production plant in Oppau, adding fertilizers to its product range. BASF also acquired and began mining anhydrite for gypsum at the Kohnstein in 1917.

IG Farben

In 1916, BASF started operations at a new site in Leuna, where explosives were produced during the First World War. On 21 September 1921, an explosion occurred in Oppau, killing 565 people. The Oppau explosion was the biggest industrial accident in German history. Under the leadership of Carl Bosch - a critic of Nazi policies - BASF founded IG Farben with Hoechst, Bayer, and three other companies, thus losing its independence. BASF was the nominal survivor, as all shares were exchanged for BASF shares prior to the merger. Rubber, fuels, and coatings were added to the range of products. 

World War II

Following the appointment of Adolf Hitler as Chancellor in 1933, IG Farben collaborated with the Nazi regime, profiting from guaranteed volumes and prices, and from the slave labor provided by the government's Nazi concentration camps. IG Farben also achieved notoriety owing to its production of Zyklon-B, the lethal gas used to murder prisoners in German Nazi extermination camps. In 1935, IG Farben and AEG presented the magnetophon – the first tape recorder – at the Radio Exhibition in Berlin.

The Ludwigshafen site was almost completely destroyed during the Second World War and was subsequently rebuilt. The allies dissolved IG Farben in November 1945.

Both the Ludwigshafen and Oppau plants were of strategic importance for the war because the German military needed many of their products, e.g., synthetic rubber and gasoline. As a result, they were major targets for air raids. Throughout the war, Allied bombers attacked the plants 65 times.
Shelling took place from the autumn of 1943 and saturation bombing inflicted extensive damage. Production virtually stopped by the end of 1944.

Due to a shortage of male workers during the war, women were conscripted to work in the factories, and later prisoners of war and foreign civilians. Concentration camp inmates did not work at the Ludwigshafen and Oppau plants.

In July 1945, the American military administration confiscated the entire assets of IG Farben. That same year, the Allied Commission decreed that IG Farben should be dissolved. The sites at Ludwigshafen and Oppau were controlled by French authorities. 

BASF refounded

On 28 July 1948, an explosion occurred at a BASF site in Ludwigshafen, killing 207 people and injuring 3818. In 1952, BASF was refounded under its own name following the efforts of former Nazi Party member and Third Reich Wehrwirtschaftsführer (war economy leader) Carl Wurster. With the German economic miracle in the 1950s, BASF added synthetics such as nylon to its product range. BASF developed polystyrene in the 1930s and invented Styropor in 1951. 

Production abroad

In the 1960s, production abroad was expanded and plants were built in Argentina, Australia, Belgium, Brazil, France, India, Italy, Japan, Mexico, Spain, United Kingdom and the United States. Following a change in corporate strategy in 1965, greater emphasis was placed on higher-value products such as coatings, pharmaceuticals, pesticides and fertilizers. Following German reunification, BASF acquired a site in Schwarzheide, eastern Germany, on 25 October 1990. It expanded to Podolsk, Russia, in 2012, and to Kazan in 2013.

The company announced the start of a US$10 billion investment project at Zhanjiang, China, in November 2019. This ″Verbund″ site is intended for the production of engineering plastics and TPU. The site would be the third-largest BASF site worldwide, following Ludwigshafen, Germany, and Antwerp, Belgium, and is expected to be operational by 2022.

Takeovers

In 1968 BASF (together with Bayer AG) bought the German coatings company Herbol. BASF completely took over the Herbol branches in Cologne and Würzburg in 1970. Under new management, the renewal and expansion of the trademark continued. After an extensive reorganisation and an increasing international orientation of the coatings business, Herbol became part of the new founded Deco GmbH in 1997.

BASF bought the Wyandotte Chemical Company, and its Geismar, Louisiana chemical plant in the early 1980s. The plant produced plastics, herbicides, and antifreeze. BASF soon tried to operate union-free, having already reduced or eliminated union membership in several other US plants. Challenging the Geismar OCAW union resulted in a labor dispute that saw members locked out from 1984-1989 and eventually winning their case. A worker solidarity committee at BASF's headquarters plant in Ludwigshafen, Germany, took donations from German workers to support the American strikers and organized rallies and publicity in support. The dispute was the subject of an academic study The union also exposed major accidental releases of phosgene, toluene and other toxic gases, these being publicized in the local media and through a video, Out of Control. A court threw out a $66,700 fine against BASF for five environmental violations as "too small".

BASF's European coatings business was taken over by AkzoNobel in 1999. BASF bought the Engelhard Corporation for $4.8 billion in 2006. Other acquisitions in 2006 were the purchase of Johnson Polymer and the construction chemicals business of Degussa.

The acquisition of Johnson Polymer was completed on 1 July 2006. The purchase price was $470 million on a cash and debt-free basis. It provided BASF with a range of water-based resins that complements its portfolio of high solids and UV resins for the coatings and paints industry and strengthened the company's market presence, particularly in North America.

BASF Portsmouth Site in the West Norfolk area of Portsmouth, Virginia, United States. The plant is served by the Commonwealth Railway.

The acquisition of Degussa AG's construction chemicals business was completed in 2006. The purchase price for equity was about €2.2 billion. In addition, the transaction was associated with a debt of €500 million.

The company agreed to acquire Ciba (formerly part of Ciba-Geigy) in September 2008. The proposed deal was reviewed by the European Commissioner for Competition. On 9 April 2009, the acquisition was officially completed.

On 19 December 2008, BASF acquired U.S.-based Whitmire Micro-Gen together with U.K.-based Sorex Ltd, Widnes, Great Britain. Sorex is a manufacturer of branded chemical and non-chemical products for professional pest management. In March 2007 Sorex was put up for sale with a price tag of about £100 million.

In December 2010, BASF completed the acquisition of Cognis.

In May 2015, BASF agreed to sell parts of its pharmaceutical ingredients business to Swiss drug manufacturer Siegfried Holding for a fee of €270 million, including assumed debt.

In October 2017, BASF announced it would buy seed and herbicide businesses from Bayer for €5.9 billion ($7 billion), as part of its acquisition of Monsanto.

In August 2019, BASF agreed to sell its global pigments business to Japanese fine chemical company DIC for €1.15 billion ($1.28 billion) on a cash and debt-free basis.

In September 2019, BASF signed an agreement with DuPont Safety & Construction, a subsidiary business unit of DuPont Co., to sell its ultrafiltration membrane business, Inge GmbH. According to BASF executives, Inge Gmbh and its products fit better with DuPont and their business strategy.

Finances

For the fiscal year 2017, BASF reported earnings of EUR€6.1 billion, with an annual revenue of EUR€64.5 billion, an increase of 12% over the previous fiscal cycle. BASF's shares traded at over €69 per share, and its market capitalization was valued at US€63.7 billion in November 2018. In October 2019, BASF reported a drop of operating income for July to September amounting to 24 percent, along with a drop in EBIT earnings of €1.1 billion ($1.2 billion). The US-China trade war as well as uncertainties related to Brexit were identified as contributing factors. However, overall third quarter profit beat expectations as the acquisition of Bayer AG's agrochemical and seed business help to offset some of the effects of the trade war.

Year Revenue
in bn. EUR€
Net income
in bn. EUR€
Total Assets
in bn. EUR€
Employees
2013 73.973 4.842 64.382 112,206
2014 74.326 5.155 71.359 113,292
2015 70.449 3.987 70.836 112,435
2016 57.550 4.056 76.496 113,830
2017 61.223 6.078 78.768 115,490
2018 62.675 4.707 86.556 122,404

Business segments

Former BASF building in Ludwigshafen
 
BASF headquarters, Ludwigshafen, Germany
 
BASF operates in a variety of markets. Its business is organized in the segments of Chemicals, Plastics, Performance Products, Functional Solutions, Agricultural Solutions, and Oil and Gas.

Chemicals

BASF produces a wide range of chemicals such as solvents, amines, resins, glues, electronic-grade chemicals, industrial gases, basic petrochemicals, and inorganic chemicals. The most important customers for this segment are the pharmaceutical, construction, textile, and automotive industries. 

Plastics

BASF's plastic products include high-performance materials in thermoplastics, foams, and urethanes.

Engineering Plastics
 
BASF's Engineering Plastics consists of the "4 Ultras" - Ultramid polyamide (PA) nylon-based resins, Ultradur, polybutylene terephthalate (PBT), Ultraform, polyacetal (POM), and Ultrason, polysulfone (PSU) and polyethersulfone (PES).

Styrenics
 
BASF Styrenics consists of the Foams and Copolymers. BASF's styrenic copolymers have applications in electronics, building and construction, and automotive components. In 2011 BASF and INEOS blended their global business activities in the fields of styrene monomers (SM), polystyrene (PS), acrylonitrile butadiene styrene (ABS), styrene butadiene copolymers (SBC) and other styrene-based copolymers (SAN, AMSAN, ASA, MABS) into a joint venture named Styrolution.

Polyurethanes
 
BASF's Polyurethanes business consists of diverse technologies and finished products. Urethane chemicals are raw materials used in rigid and flexible foams commonly used for insulation in the construction and appliance industries, furniture, packaging, and transportation.
 
Foams
 
Foams like Styropor are generally used as insulating materials. They are eco-efficient and offer advantages over other materials in terms of cost-effectiveness, preservation of resources and environmental protection. Investments made for insulating materials usually pay for themselves within a short time and contribute to retaining and even enhancing the value of buildings. 

Polyamides and Intermediates
 
BASF manufactures polyamide precursors and polyamide


Biodegradable plastics
 
BASF developed a biodegradable plastic with a high content of polylactic acid.

Performance products

BASF produces a range of performance chemicals, coatings and functional polymers. These include raw materials for detergents, textile and leather chemicals, pigments and raw materials for adhesives, paper chemicals. Customers are the automotive, oil, paper, packaging, textile, sanitary products, detergents, construction materials, coatings, printing, and leather industries.

Functional Solutions

BASF-sponsored Museum for Laquerware in Münster, Germany
 
BASF in Ludwigshafen
 
BASF's Functional Solutions segment consists of the Catalysts, Construction Chemicals and Coatings divisions. These divisions develop customer-specific products, in particular for the automotive and construction industries. 

Agricultural

BASF supplies agricultural products and chemicals including fungicides, herbicides, insecticides and seed treatment products. The company also researches nutrigenomics. BASF opened a new crop protection technology center in Limburgerhof, Germany in 2016.

Biotechnology

BASF was cooperating with Monsanto Company in research, development and marketing of biotechnology. In correlation to this work, BASF has licensed many gene editing tools including CRISPR Cas9 and CRISPR Cpf1.

The BASF Plant Science subsidiary produces the Amflora and Starch Potato genetically modified potato with reduced amylose. In 2010 BASF conducted Department of Environment, Food and Rural Affairs approved trials of genetically modified potatoes in the United Kingdom. Starch Potato was authorised for use in USA in 2014. 

Other GM crops are Phytaseed Canola varieties with phytase, sulfonylurea herbicide tolerant soybean and drought tolerant corn (with cold shock protein B) developed with Monsanto.

Oil and gas

BASF explores for and produces oil and gas through its subsidiary Wintershall Holding AG. In Central and Eastern Europe, Wintershall works with its Russian partner Gazprom

Investors

75% of the BASF shares are held by institutional investors (BlackRock more than 5%). 36% of the shares are held in Germany, 11% in the UK and 17% in the U.S.

Production

Ludwigshafen production site at night.
 
BASF's recent success is characterized by a focus on creating resource efficient product lines after completely abandoning consumer products. This strategy was reflected in production by a re-focus towards integrated production sites. The largest such integrated production site is located in Ludwigshafen employing 33,000 people.

Integrated production sites are characterized by co-location of a large number of individual production lines (producing a specific chemical), which share an interconnected material flow. Piping is used ubiquitously for volume materials. All production lines use common raw material sourcing and feed back waste resources, which can be used elsewhere (e.g. steam of various temperatures, sulfuric acid, carbon monoxide). The economic incentive for this approach is high resource and energy efficiency of the overall process, reduced shipping cost and associated reduced risk of accidents. Due to the high cost of such an integrated production site, it establishes a high entry barrier for competitors trying to enter the market for volume chemicals. 

BASF built a new chemical complex in Dahej, Gujarat at a cost of $100 million. This facility has South Asia's first methylene diphenyl diisocyanate (MDI) splitter for processing crude MDI. BASF has 8 production facilities in India.

BASF SE has succeeded in developing a semi-crystalline polyamide that allows light to pass through largely unhindered. Ultramid Vision combines very high light transmission with low light scattering. This makes it the world's first semi-crystalline polyamide for semi-transparent or transparent components in chemically challenging environments. Additionally, the unique polyamide is UV and temperature resistant, scratch-proof as well as suitable for flame-retardant requirements. Ultramid Vision can be used in various application fields: It recommends itself especially for parts for visual check, illumination or light design. Ultramid Vision presents a versatile alternative to commonly used materials such as amorphous aliphatic polyamides, polycarbonate or styrene-acrylonitrile copolymers.

Environmental record

In 2006 BASF was included in the Climate Leadership Index for their efforts in relation to climate change and greenhouse gas emissions.

BASF has created filters for wastewater treatment plants that help to reduce emissions.

The BASF Company and Columbia University formed a partnership to further research “environmentally benign and sustainable energy sources”. The company has recently reported their emissions in 2006 to be “1.50 million metric tons of waste,” which is a decrease from previous years. The amount of waste BASF produces has continued to fall.

While BASF publishes its environmental information in the US and Europe, Greenpeace has expressed deep concerns at BASF's refusal to release environmental information on its operations in China.

In May 2009, a BASF Plant in Hannibal, Missouri, United States, accidentally discharged chromium into the Mississippi River. The local Department of Natural Resources performed tests in December 2009 showing the chromium levels did not exceed regulatory safety limits. BASF worked with the Missouri Department of Natural Resources (MoDNR) to resolve questions regarding the elevated level of hexavalent chromium that was detected in the effluent from one of its permitted outfalls into the Mississippi River. The state department of health reviewed the test results and determined that the amounts found were well below recommended public health screening levels.

In 2013, BASF reported a spill of several hundred kilograms of the chelating agent Trilon-B (tetrasodium EDTA) into the river Rhine from BASF's headquarters in Ludwigshafen, Germany.

Chewing gum

From Wikipedia, the free encyclopedia
 
Chewing gum
Chewing gum stick.jpg
An unwrapped stick of chewing gum
TypeConfectionery
Main ingredientsgum base, sweeteners, plasticizers, flavors, colors, polyols

Chewing gum is a soft, cohesive substance designed in order to be chewed without being swallowed. Modern chewing gum is composed of gum base, sweeteners, softeners/plasticizers, flavors, colors, and, typically, a hard or powdered polyol coating. Its texture is reminiscent of rubber because of the physical-chemical properties of its polymer, plasticizer, and resin components, which contribute to its elastic-plastic, sticky, chewy characteristics.

History

Sticks of Fruit Stripe chewing gum.
 
The cultural tradition of chewing gum seems to have developed through a convergent evolution process, as traces of this habit have arisen separately in many of the early civilizations. Each of the early precursors to chewing gum were derived from natural growths local to the region and were chewed purely out the instinctual desire to masticate. Early chewers did not necessarily desire to derive nutritional benefits from their chewable substances, but at times sought taste stimuli and teeth cleaning or breath-freshening capabilities.

Chewing gum in many forms has existed since the Neolithic period. 6,000-year-old chewing gum made from birch bark tar, with tooth imprints, has been found in Kierikki in Finland. The tar from which the gums were made is believed to have antiseptic properties and other medicinal benefits. It is chemically similar to petroleum tar and is in this way different from most other early gum. The Mayans and Aztecs were the first to exploit the positive properties of gum, they used chicle, a natural tree gum, as a base for making a gum-like substance and to stick objects together in everyday use. Forms of chewing gums were also chewed in Ancient Greece. The Ancient Greeks chewed mastic gum, made from the resin of the mastic tree. Mastic gum, like birch bark tar, has antiseptic properties and is believed to have been used to maintain oral health. Both chicle and mastic are tree resins. Many other cultures have chewed gum-like substances made from plants, grasses, and resins.

Variations of early chewing gum worldwide 
Ancient civilization Chewing gum precursor
Ancient Greece Mastic tree bark
Ancient Maya Chicle
Chinese Ginseng plant roots
Eskimos Blubber
Native Americans Sugar pine and spruce sap
South Americans Coca leaves
South Asia (India) Betel nuts
United States (early settlers) Tobacco leaves

Although chewing gum can be traced back to civilizations around the world, the modernization and commercialization of this product mainly took place in the United States. The American Indians chewed resin made from the sap of spruce trees. The New England settlers picked up this practice, and in 1848, John B. Curtis developed and sold the first commercial chewing gum called The State of Maine Pure Spruce Gum. In this way, the industrializing West, having forgotten about tree gums, rediscovered chewing gum through the First Americans. Around 1850 a gum made from paraffin wax, which is a petroleum product, was developed and soon exceeded the spruce gum in popularity. To sweeten these early gums, the chewer would often make use of a plate of powdered sugar, which they would repeatedly dip the gum in to maintain sweetness. William Semple filed an early patent on chewing gum, patent number 98,304, on December 28, 1869.

An image of a Colgan's Taffy Tolu Chewing Gum chromolithograph advertisement circa 1910
 
The first flavored chewing gum was created in the 1860s by John Colgan, a Louisville, Kentucky pharmacist. Colgan mixed with powdered sugar the aromatic flavoring tolu, a powder obtained from an extract of the balsam tree (Myroxylon), creating small sticks of flavored chewing gum he named "Taffy Tolu". Colgan also lead the way in the manufacturing and packaging of chicle-based chewing gum, derived from Manilkara chicle, a tropical evergreen tree. He licensed a patent for automatically cutting chips of chewing gum from larger sticks: US 966,160 "Chewing Gum Chip Forming Machine" August 2, 1910 and a patent for automatically cutting wrappers for sticks of chewing gum: US 913,352 "Web-cutting attachment for wrapping-machines" February 23, 1909 from Louisville, Kentucky inventor James Henry Brady, an employee of the Colgan Gum Company. 

Modern chewing gum was first developed in the 1860s when chicle was brought from Mexico by the former President, General Antonio Lopez de Santa Anna, to New York, where he gave it to Thomas Adams for use as a rubber substitute. Chicle did not succeed as a replacement for rubber, but as a gum, which was cut into strips and marketed as Adams New York Chewing Gum in 1871. Black Jack (1884), which is flavored with licorice, Chiclets (1899), and Wrigley's Spearmint Gum were early popular gums that quickly dominated the market and are all still around today. Chewing gum gained worldwide popularity through American GIs in WWII, who were supplied chewing gum as a ration and traded it with locals. Synthetic gums were first introduced to the U.S. after chicle no longer satisfied the needs of making good chewing gum. By the 1960s, US manufacturers had switched to butadiene-based synthetic rubber, as it was cheaper to manufacture.

Ingredient composition

Gum base composition is considered proprietary information known by select individuals within each gum-manufacturing company. Information about the other components of chewing gum are more accessible to the public and they are listed in Table 2.

Table 2: Common Ingredients in the Formulation of Modern Chewing Gum
Ingredient Percent (by weight) Composition Functionality Common Examples
Gum Base 25-35% Although the formulation of gum bases is considered proprietary information for industry competitors, three main components make up all gum bases: resin, wax, and elastomer. Resin (ex. terpene) is the main chewable portion. Wax softens the gum. Elastomers add flexibility. The molecular composition of gum base is very similar to that of plastics and rubbers. Natural or Synthetic Ingredients (See Table 3)
Sweeteners Sugar Alcohols: 40-50% Artificial Sweeteners: 0.05-0.5%
Bulk Polyol Sweeteners are responsible for initial sweetness, whereas intensive sweeteners are intended for prolonging the sweetness effect. Intensive Sweeteners are often encapsulated to delay the release of flavor. Bulk Polyol Sweeteners[20]: sugar, dextrose, glucose or corn syrup, erythritol, isomalt, xylitol, maltitol, mannitol, sorbitol, lactitol
Intensive Sweeteners[21]: aspartame, acesulfame-K, saccharine, sucralose, neohesperidine, dihydrichalcone
Glycerine 2-15% To maintain moistness.
Softener/Plasticizer 1-2% To soften gum by increasing flexibility and reducing brittleness by altering the glass transition temperature. Quantities of this additive are altered in order to balance processability and packaging speed. lecithin, hydrogenated vegetable oils, glycerol ester, lanolin, methyl ester, pentaerythritol ester, rice bran wax, stearic acid, sodium and potassium stearates
Flavors 1.5-3.0% For taste and sensory appeal. Flavor components in gum exist in liquid, powder or micro-encapsulated forms. Liquid flavor incorporations are either water-soluble, oil-soluble, or water-dispersible emulsions. The oil-soluble flavors remain in the gum longer, resulting in longer lasting flavor sensations, because the gum base is hydrophobic and attracted to oil-based components. Natural or synthetic Peppermint and spearmint are the most popular flavors. Food acids are implemented to provide a sour flavor (i.e. citric, tartaric, malic, lactic, adipic, and fumaric acids).
Colors Variable For visual appeal. Natural or Synthetic
Polyol Coating Variable Pellet gum's characteristic hard outer shell is due to a polyol coating. Polyols can also be implemented as a water absorbent powder dusting in order to maintain the quality and extend the shelf life of the product. These humectants bind water by establishing many hydrogen bonds with water molecules. Sorbitol Maltitol/Isomalt
Mannitol
Starch

Gum base

Gum base is made of polymers, plasticizers, and resins. Polymers, including elastomers, are responsible for the stretchy and sticky nature of chewing gum. Plasticizers improve flexibility and reduce brittleness, contributing to the plastic and elastic nature of gum. The interactions of plasticizers within gum base are governed by solubility parameters, molecular weight, and chemical structure. Resins compose the hydrophobic portion of the gum base, responsible for its chewiness. Although the exact ingredients and proportions used in each brand's gum base are trade secrets within the gum industry, Table 3 lists all of the natural and synthetic gum base components approved for use in the United States, demonstrating some examples of key gum base components.

Table 3: Gum Base Ingredients Approved for Use by the U.S. Food and Drug Administration (2016)
Natural Ingredients Synthetic Ingredients
Sapotaceae Chicle
Chiquibul
Crown Gum
Gutta hang kang
Massaranduba balata
Massaranduba chocolate
Nispero
Rosidinha
Venezuelan chicle
Butadiene-styrene rubber Isobutylene-isoprene copolymer (butyl rubber)
Paraffin (via the Fischer-Tropsch process)
Petroleum wax
Petroleum wax synthetic
Polyethylene
Polyisobutylene Polyvinyl acetate
Apocynaceae Jelutong
Leche caspi (sorva)
Pendare
Perillo
Moraceae Leche de vaca
Niger gutta
Tunu (tuno)
Euphorbiaceae Chilte
Natural rubber

Manufacturing process

First, gum base is previously prepared through a melting and straining or filtering process. The formulation for gum base is proprietary information known to few individuals within each gum-producing company. Next, other ingredients such as nutritive and non-nutritive sweeteners and flavors are added to the gum base until the warm mixture thickens like dough. The gum base mixture is heated during this mixing process in order to increase the entropy of the polymers to achieve a more uniform dispersion of ingredients. Then, extrusion technology is implemented to smooth, form, and shape the gum. Next, the gum goes through a shaping process that is determined by gum type and consumer demand. For example, cut and wrap (chunk or cube) pieces are severed straight out of the extruder using a vertical cutter. Sheeting is a technique often used for stick, slab and tab gums. Next, gum is either conditioned by being sprinkled with a powdered polyol or coated via the application of subsequent layers of coating using temperature controlled coating basins before it is sent to packaging.

Product varieties

Chewing gum balls

Chewing gum can come in a variety of formats ranging from 1.4 to 6.9 grams per piece, and products can be differentiated by the consumers’ intent to form bubbles or the sugar/sugarless dichotomy.

Chewing gum typically comes in three formats: tablets, coated pellets, and sticks/ slabs. Bubble gum typically come in three formats as well: tablets, hollow balls, and cubes or chunks. Stick, slab, and tab gums typically come in packs of about five to 17 sticks or more, and their medium size allows for softer texture. Pellet gums, or dragée gums, are pillow shaped pieces that are almost always coated. Packaging of pellet gums can vary from boxes to bottles to blister packs. The coating of pellet gum allows for the opportunity for multiple flavor sensations, since coating is done in a layering process and different flavor attributes can be added to various layers. Cube or chunk gums, which are typically intended for bubble blowing, are called cut and wrap gums as they are typically severed from continuous strands of extruded gum and packaged directly.

Quality and safety

Chewing gum is rather shelf stable because of its non-reactive nature and low moisture content. The water activity of chewing gum ranges from 0.40 to 0.65. The moisture content of chewing gum ranges from three to six percent. In fact, chewing gum retains its quality for so long that, in most countries, it is not required by law to be labeled with an expiration date. If chewing gum remains in a stable environment, over time the gum may become brittle or lose some of its flavor, but it will never be unsafe to eat. If chewing gum is exposed to moisture, over time water migration may occur, making the gum soggy. In lollipops with a gum center, water migration can lead to the end of the product's shelf life, causing the exterior hard candy shell to soften and the interior gum center to harden.

Physical and chemical characteristics

The physical and chemical properties of chewing gum impact all aspects of this product, from manufacturing to sensory perception during mastication. 

Chewiness

The polymers that make up the main component of chewing gum base are hydrophobic. This property is essential because it allows for retention of physical properties throughout the mastication process. Because the polymers of gum repel water, the water-based saliva system in a consumer's mouth will dissolve the sugars and flavorings in chewing gum, but not the gum base itself. This allows for gum to be chewed for a long period of time without breaking down in the mouth like conventional foods. Chewing gum can be classified as a product containing a liquid phase and a crystalline phase, providing gum with its characteristic balance of plastic and elastic properties.

Stickiness

While hydrophobic polymers beneficially repel water and contribute to chewiness, they also detrimentally attract oil. The stickiness of gum results from this hydrophobic nature, as gum can form bonds and stick when it makes contact with oily surfaces such as sidewalks, skin, hair, or the sole of one's shoe. To make matters worse, unsticking the gum is a challenge because the long polymers of the gum base stretch, rather than break. The sticky characteristic of gum may be problematic during processing if the gum sticks to any machinery or packaging materials during processing, impeding the flow of product. Aside from ensuring that the machinery is free from lipid-based residues, this issue can be combatted by the conditioning and coating of gum toward the end of the process. By adding either a powder or a coating to the exterior of the gum product, the hydrophobic gum base binds to the added substance instead of various surfaces with which it may come in contact.

Bubble-blowing capability

Bubblegum bubble.
 
Bubblegum bubbles are formed when the tension and elasticity of gum polymers acts against the constant and equally dispersed pressure of air being directed into the gum bolus. Bubble gum bubbles are circular because pressure from the focused air being directed into the bolus acts equally on all of the interior surfaces of the gum cud, uniformly pushing outward on all surfaces as the polymers extend. As the bubble expands, the polymers of the gum base stretch and the surface of the bubble begins to thin. When the force of the air being blown into the bubble exceeds the force that the polymers can withstand, the polymers overextend and the bubble pops. Due to the elastic attributes of chewing gum, the deflated bubble recoils and the wad of gum is ready to continue being chewed.

Gum bases with higher molecular weights are typically used in gums intended to meet bubble-forming expectations. Higher molecular weight gum bases include longer polymers that are able to stretch further, and thus are able to form larger bubbles that retain their shape for a longer time.

Flavor release

Flavor delivery is extended throughout the mastication process by timed release of different flavor components due to the physical-chemical properties of many of chewing gum's ingredients. Entropy is a key player in the process of flavor delivery; because some gum components are more soluble in saliva than gum base and because over time flavor components desire to increase their entropy by becoming dispersed in the less ordered system of the mouth than in the more ordered system of the gum bolus, flavor delivery occurs. During the first three to four minutes of the chew, bulking agents such as sugar or sorbitol and maltitol have the highest solubility and, therefore, are chewed out first. As these components dissolve in the consumers’ saliva and slide down the esophagus, they are no longer retained in the gum base or perceived by the chewer. During the next phase of the chew in the four to six minute range, intense sweeteners and some acids are dissolved and chewed out. These components last slightly longer than the bulking agents because they have a slightly lower solubility. Next, encapsulated flavors are released during either 10-15 minute into the chew or after 30–45 minutes. Encapsulated flavors remain incorporated in the gum base longer because the molecules that they are encapsulated in are more easily held within the gum matrix. Finally, during the last phase of the chew, softeners such as corn syrup and glycerin and other textural modifiers are dissolved, resulting in a firming up of the gum and the end of the chew.

Studies have shown that gum flavor is perceived better in the presence of sweetener. Companies have started to create chemical systems in gum so that the sweetener and flavor release together in a controlled manner during chewing.

Cooling sensation

A cooling sensation is achieved through the chemical phenomenon of the negative enthalpy of dissolution that occurs with bulk sweeteners, such as the sugar alcohols. The enthalpy of dissolution refers to the overall amount of heat that is absorbed or released in the dissolving process. Because the bulk sweeteners absorb heat as they dissolve and have a negative enthalpy, they yield a cooling sensation as they are dissolved in a consumer's saliva.

Health effects


Brain function

A review about the cognitive advantages of chewing gum by Onyper et al. (2011) found strong evidence of improvement for the following cognitive domains: working memory, episodic memory and speed of perception. However the improvements were only evident when chewing took place prior to cognitive testing. The precise mechanism by which gum chewing improves cognitive functioning is however not well understood. The researchers did also note that chewing-induced arousal could be masked by the distracting nature of chewing itself, which they named "dual-process theory", which in turn could explain some of the contradictory findings by previous studies. They also noticed the similarity between mild physical exercise such as pedaling a stationary bike and chewing gum. It has been demonstrated that mild physical exercise leads to little cognitive impairment during the physical task accompanied by enhanced cognitive functioning afterwards. Furthermore, the researchers noted that no improvement could be found for verbal fluency, which is in accordance with previous studies. This finding suggests that the effect of chewing gum is domain specific. The cognitive improvements after a period of chewing gum have been demonstrated to last for 15–20 minutes and decline afterwards.

Dental health

Sugar-free gum sweetened with xylitol has been shown to reduce cavities and plaque. The sweetener sorbitol has the same benefit, but is only about one-third as effective as xylitol. Other sugar substitutes, such as maltitol, aspartame and acesulfame K, have also been found to not cause tooth decay. Xylitol is specific in its inhibition of Streptococcus mutans, bacteria that are significant contributors to tooth decay. Xylitol inhibits Streptococcus mutans in the presence of other sugars, with the exception of fructose. Xylitol is a safe sweetener that benefits teeth and saliva production because, unlike most sugars, it is not fermented to acid. Daily doses of xylitol below 3.44 grams are ineffective and doses above 10.32 grams show no additional benefit. Other active ingredients in chewing gum include fluoride, which strengthens tooth enamel, and p-chlorbenzyl-4-methylbenzylpiperazine, which prevents travel sickness. Chewing gum also increases saliva production.

Food and sucrose have a demineralizing effect upon enamel that has been reduced by adding calcium lactate to food. Calcium lactate added to toothpaste has reduced calculus formation. One study has shown that calcium lactate enhances enamel remineralization when added to xylitol-containing gum, but another study showed no additional remineralization benefit from calcium lactate or other calcium compounds in chewing-gum.

Other studies indicated that the caries preventive effect of chewing sugar-free gum is related to the chewing process itself rather than being an effect of gum sweeteners or additives, such as polyols and carbamide. A study investigated the in situ effect of casein phosphopeptide–amorphous calcium phosphate (CPP–ACP) found that its incorporation into a sugar-free gum increases the remineralization / protection of eroded enamel surface significantly.

Gum chewing is regarded as a helpful way to cure halitosis (bad breath). Chewing gum not only helps to add freshness to breath but can aid in removing food particles and bacteria associated with bad breath from teeth. It does this by stimulating saliva, which essentially washes out the mouth. Chewing sugar-free gum for 20 minutes after a meal helps prevent tooth decay, according to the American Dental Association, because the act of chewing the sugar-free gum produces saliva to wash away bacteria, which protects teeth. Chewing gum after a meal replaces brushing and flossing, if that's not possible, to prevent tooth decay and increase saliva production. Chewing gum can also help with the lack of saliva or xerostomia since it naturally stimulates saliva production. Saliva is made of chemicals, such as organic molecules, inorganic ions and macromolecules. 0.5% of saliva deals with dental health, since tooth enamel is made of calcium phosphate, those inorganic ions in saliva help repair the teeth and keep them in good condition. The pH of saliva is neutral, which having a pH of 7 allows it to remineralize tooth enamel. Falling below a pH of 5.5 (which is acidic) causes the saliva to demineralize the teeth.

Masumoto et al. looked at the effects of chewing gum after meals following an orthodontic procedure, to see if chewing exercises caused subjects pain or discomfort, or helped maintain a large occlusal contact area. 35 adult volunteers chewed gum for 10 to 15 minutes before or after three meals each day for 4 weeks. 90% of those questioned said that the gum felt "quite hard", and half reported no discomfort.

Use in surgery

Several randomized controlled studies have investigated the use of chewing gum in reducing the duration of post-operative ileus following abdominal and specifically gastrointestinal surgery. A systematic review of these suggests gum chewing, as a form of "sham feeding", is a useful treatment therapy in open abdominal or pelvic surgery, although the benefit is less clear when laparoscopic surgical techniques are used.

Chewing gum after a colon surgery helps the patient recover sooner. If the patient chews gum for fifteen minutes for at least four times per day, it will reduce their recovery time by a day and a half. The average patient took 0.66 fewer days to pass gas and 1.10 fewer days to have a bowel movement. Saliva flow and production is stimulated when gum is chewed. Gum also gets digestive juices flowing and is considered "sham feeding". Sham feeding is the role of the central nervous system in the regulation of gastric secretion.

Stomach

Chewing gum is used as a novel approach for the treatment of gastroesophageal reflux disease (GERD). One hypothesis is that chewing gum stimulates the production of more bicarbonate-containing saliva and increases the rate of swallowing. After the saliva is swallowed, it neutralizes acid in the esophagus. In effect, chewing gum exaggerates one of the normal processes that neutralize acid in the esophagus. However, chewing gum is sometimes considered to contribute to the development of stomach ulcers. It stimulates the stomach to secrete acid and the pancreas to produce digestive enzymes that aren't required. In some cases, when consuming large quantities of gum containing sorbitol, gas and/or diarrhea may occur.

Controversies


Classification as food

Controversy arises as to health concerns surrounding the questionable classification of gum as food, particularly in regard to some alternative uses for gum base ingredients. According to the U.S. Food and Drug Administration (FDA), chewing gum is considered a food, as the term “food” means “a raw, cooked, or processed edible substance, ice, beverage, or ingredient used or intended for use or for sale in whole or in part for human consumption, or chewing gum”. Chewing gum is defined as a food of minimal nutritional value. However, many of the ingredients in gum base have uses in inedible products, which raises concern in some consumers. Polyethylene, one of the most popular components of gum base, belongs to a common group of plastics and is used in products from plastic bags to hula hoops. Polyvinyl acetate is a sticky polymer found in white glue. Butyl rubber is typically used in caulking and the lining of car tires, in addition to its role in gum base. Paraffin wax is a byproduct of refined petroleum.

Possible carcinogens

Concern has arisen about the possible carcinogenicity of the vinyl acetate (acetic acid ethenyl ester) used by some manufacturers in their gum bases. Currently, the ingredient can be hidden in the catch-all term "gum base". The Canadian government at one point classified the ingredient as a "potentially high hazard substance." However, on January 31, 2010, the Government of Canada's final assessment concluded that exposure to vinyl acetate is not considered to be harmful to human health. This decision under the Canadian Environmental Protection Act (CEPA) was based on new information received during the public comment period, as well as more recent information from the risk assessment conducted by the European Union.

Choking and excretion of swallowed gum

Various myths hold that swallowed gum will remain in a human's stomach for up to seven years, as it is not digestible. According to several medical opinions, there seems to be little truth behind the tale. In most cases, swallowed gum will pass through the system as quickly as any other food.

There have been cases where swallowing gum has resulted in complications in young children requiring medical attention. A 1998 paper describes a four-year-old boy being referred with a two-year history of constipation. The boy was found to have "always swallowed his gum after chewing five to seven pieces each day", being given the gum as a reward for good behavior, and the build-up resulted in a solid mass which could not leave the body. A 1½-year-old girl required medical attention when she swallowed her gum and four coins, which got stuck together in her esophagus. A bezoar is formed in the stomach when food or other foreign objects stick to gum and build up, causing intestinal blockage. As long as the mass of gum is small enough to pass out of the stomach, it will likely pass out of the body easily, but it is recommended that gum not be swallowed or given to young children who do not understand not to swallow it.

Adults have choked to death on chewing gum in rare cases. A 2012 report describes a 42-year-old woman who fell on the stairs while chewing gum. Due to the impact, the gum fell into the pharynx and was inhaled into the larynx, causing complete blockage and resulting in the woman's death by asphyxiation.

Environmental effects

Chewing gum on a sidewalk in Reykjavík
 
Chewing gum is not water-soluble and unlike other confectionery is not fully consumed. There has been much effort at public education and investment aimed at encouraging responsible disposal. Despite this it is commonly found stuck underneath benches, tables, handrails and escalators. It is extremely difficult and expensive to remove once "walked in" and dried. Gum bonds strongly to asphalt and rubber shoe soles because they are all made from polymeric hydrocarbons. It also bonds strongly with concrete paving. Removal is generally achieved by steam jet and scraper but the process is slow and labour-intensive.

Most external urban areas with high pedestrian traffic show high incidence of casual chewing gum discard. In 2000 a study on Oxford Street, one of London's busiest shopping streets, showed that a quarter of a million black or white blobs of chewing gum were stuck to its pavement. Gum removal from city streets, or even famous landmarks, can be a costly effort; in Rome, 15,000 pieces of chewed gum are discarded on a daily basis and the removal of each piece costs the city one euro. However, likely as a consequence of Singapore's ban, Singapore's pavements are, perhaps uniquely amongst modern cities, free of gum. 

Various teams of researchers have developed gum that is less adhesive and degrades within days or weeks. One example, Rev7 Gum, was briefly for sale from 2010 to 2012. 

Bans

Many schools do not allow chewing gum because students often dispose of it inappropriately (leaving it under desks and chairs, behind vending machines, etc.). The chewing may also pose a distraction to class, and the gum might carry diseases or bacteria from other students.

The Singapore government outlawed chewing gum in 1992 citing the danger of discarded gum being wedged in the sliding doors of underground trains and general cleanliness. However, in 2004 the government allowed sugarless gum to be sold in pharmacies if a doctor or dentist prescribed it due to the Singapore–United States Free Trade Agreement.

Recycling

Gumdrop chewing gum collecting bin
 
In 2018, the BBC published a news article on British designer Anna Bullus, who created a method of collecting and recycling chewing gum into plastic, noting that litter from chewing gum is the second most common form of litter, second only to cigarette litter. She uses a Worcester recycling plant to make old chewing gum into plastic. She then uses that plastic at a plastic moulding specialist, Amber Valley, in Leicester to make plastic objects. Known objects made are collection containers for more chewing gum, shoe soles, rubber boots, and plastic cups. Her company advertises itself as the "first company in the world to recycle and process chewing gum into a range of new compounds that can be used in the rubber and plastics industry". The company is called Gum-tec, and the collection containers are dubbed "gumdrops". Advertised products on the website are pencils, coffee mugs, guitar picks, a "bicycle spoke", rulers, sports cones, frisbees, boomerangs, door stops, "meal mates", lunch-boxes, and combs.

Butyl rubber

From Wikipedia, the free encyclopedia
 
Butyl rubber gloves
 
Butyl rubber, sometimes just called "butyl", is a synthetic rubber, a copolymer of isobutylene with isoprene. The abbreviation IIR stands for isobutylene isoprene rubber. Polyisobutylene, also known as "PIB" or polyisobutene, (C4H8)n, is the homopolymer of isobutylene, or 2-methyl-1-propene, on which butyl rubber is based. Butyl rubber is produced by polymerization of about 98% of isobutylene with about 2% of isoprene. Structurally, polyisobutylene resembles polypropylene, but has two methyl groups substituted on every other carbon atom, rather than one. Polyisobutylene is a colorless to light yellow viscoelastic material. It is generally odorless and tasteless, though it may exhibit a slight characteristic odor. 

Butyl rubber has excellent impermeability, and the long polyisobutylene segments of its polymer chains give it good flex properties. Its formula is:

 Butyl rubber formula.png

It can be made from the monomer isobutylene (CH2=C(CH3)2) only via cationic addition polymerization.

A synthetic rubber, or elastomer, butyl rubber is impermeable to air and used in many applications requiring an airtight rubber. Polyisobutylene and butyl rubber are used in the manufacture of adhesives, agricultural chemicals, fiber optic compounds, ball bladders, O-rings, caulks and sealants, cling film, electrical fluids, lubricants (2 stroke engine oil), paper and pulp, personal care products, pigment concentrates, for rubber and polymer modification, for protecting and sealing certain equipment for use in areas where chemical weapons are present, as a gasoline/diesel fuel additive, and chewing gum. The first major application of butyl rubber was tire inner tubes. This remains an important segment of its market even today.

History

Isobutylene was discovered by Michael Faraday in 1825. Polyisobutylene (PIB) was first developed by the BASF unit of IG Farben in 1931 using a boron trifluoride catalyst at low temperatures and sold under the trade name Oppanol B [de]. PIB remains a core business for BASF to this day.

It was later developed into butyl rubber in 1937, by researchers William J. Sparks and Robert M. Thomas, at Standard Oil of New Jersey's Linden, N.J., laboratory. Today, the majority of the global supply of butyl rubber is produced by two companies, ExxonMobil (one of the descendants of Standard Oil) and Polymer Corporation, a Canadian federal crown corporation established in 1942 to produce artificial rubber to substitute for overseas supply cut off by World War II. It was renamed Polysar in 1976 and the rubber component became a subsidiary, Polysar Rubber Corp. The company was privatized in 1988 with its sale to NOVA Corp which, in turn, sold Polysar Rubber in 1990 to Bayer AG of Germany. In 2005 Bayer AG spun off chemical divisions, including most of the Sarnia site, creating LANXESS AG, also of Germany.

PIB homopolymers of high molecular weight (100,000–400,000 or more) are polyolefin elastomers: tough extensible rubber-like materials over a wide temperature range; with low density (0.913–0.920), low permeability and excellent electrical properties.

In the 1950s and 1960s, halogenated butyl rubber (halobutyl) was developed, in its chlorinated (chlorobutyl) and brominated (bromobutyl) variants, providing significantly higher curing rates and allowing covulcanization with other rubbers such as natural rubber and styrene-butadiene rubber. Halobutyl is today the most important material for the inner linings of tubeless tires. Francis P. Baldwin received the 1979 Charles Goodyear Medal for the many patents he held for these developments. 

In the spring of 2013 two incidents of PIB contamination in the English Channel, believed to be connected, were described as the worst UK marine pollution 'for decades'. The RSPB estimated over 2,600 seabirds were killed by the chemical and hundreds more were rescued and decontaminated.

Uses


Fuel and lubricant additive

Polyisobutylene can be reacted with maleic anhydride to make polyisobutenylsuccinic anhydride (PIBSA), which can then be converted into polyisobutenylsuccinimides (PIBSI) by reacting it with various ethyleneamines. When used as an additive in lubricating oils and motor fuels, they can have a substantial effect on the properties of the oil or fuel. Polyisobutylene added in small amounts to the lubricating oils used in machining results in a significant reduction in the generation of oil mist and thus reduces the operator's inhalation of oil mist. It is also used to clean up waterborne oil spills as part of the commercial product Elastol. When added to crude oil it increases the oil's viscoelasticity when pulled, causing the oil to resist breakup when it is vacuumed from the surface of the water.

As a fuel additive, polyisobutylene has detergent properties. When added to diesel fuel, it resists fouling of fuel injectors, leading to reduced hydrocarbon and particulate emissions. It is blended with other detergents and additives to make a "detergent package" that is added to gasoline and diesel fuel to resist buildup of deposits and engine knock.

Polyisobutylene is used in some formulations as a thickening agent.

Explosives

Polyisobutylene is often used by the explosives industry as a binding agent in plastic explosives such as C-4. Polyisobutylene binder is used because it makes the explosive more insensitive to premature detonation as well as making it easier to handle and mold. 

Speakers and Audio Equipment

Butyl rubber is generally used in speakers, specifically the surrounds. It was used as a replacement for foam surrounds because the foam would deteriorate. The majority of modern speakers use butyl rubber, while most vintage speakers use foam. 

Sporting equipment

Butyl rubber is used for the bladders in sporting balls (e.g. Rugby balls, footballs, basketballs, netballs) to provide a tough, airtight inner compartment.

Damp proofing and roof repair

Butyl rubber sealant is used for damp proofing, rubber roof repair and for maintenance of roof membranes (especially around the edges). It is important to have the roof membrane fixed, as a lot of fixtures (e.g., air conditioner vents, plumbing, and other pipes) can considerably loosen it.

Rubber roofing typically refers to a specific type of roofing materials that are made of ethylene propylene diene monomers (EPDM rubber). It is crucial to the integrity of such roofs to avoid using harsh abrasive materials and petroleum-based solvents for their maintenance.

Polyester fabric laminated to butyl rubber binder provides a single-sided waterproof tape that can be used on metal, PVC, and cement joints. It is used for repairing and waterproofing metal roofs. 

Gas masks and chemical agent protection

Butyl rubber is one of the most robust elastomers when subjected to chemical warfare agents and decontamination materials. It is a harder and less porous material than other elastomers, such as natural rubber or silicone, but still has enough elasticity to form an airtight seal. While butyl rubber will break down when exposed to agents such as NH3 (ammonia) or certain solvents, it breaks down more slowly than comparable elastomers. It is therefore used to create seals in gas masks and other protective clothing. 

Pharmaceutical stoppers

Butyl and bromobutyl rubber are commonly used for manufacturing rubber stoppers used for sealing medicine vials and bottles.

Chewing gum

Gumdrop chewing gum collecting bin
 
Most modern chewing gum uses food-grade butyl rubber as the central gum base, which contributes not only the gum's elasticity but an obstinate, sticky quality which has led some municipalities to propose taxation to cover costs of its removal.

Recycled chewing gum has also been used as a source of recovered polyisobutylene. Amongst other products, this base rubber has been manufactured into coffee cups and 'Gumdrop' gum-collecting bins. When filled, the collecting bins and their contents are shredded together and recycled again. 

Tires

Butyl rubber and halogenated rubber are used for the innerliner that holds the air in the tire.

Insulating Windows

Polyisobutylene is used as the primary seal in an insulating glass unit for commercial and residential construction providing the air and moisture seal for the unit.

Inequality (mathematics)

From Wikipedia, the free encyclopedia https://en.wikipedia.org/wiki/Inequality...