A match is a tool for starting a fire. Typically, modern matches are made of small wooden sticks or stiff paper. One end is coated with a material that can be ignited by frictional heat generated by striking the match against a suitable surface. Wooden matches are packaged in matchboxes, and paper matches are partially cut into rows and stapled into matchbooks. The coated end of a match, known as the match "head", contains either phosphorus or phosphorus sesquisulfide as the active ingredient and gelatin as a binder. There are two main types of matches: safety matches, which can be struck only against a specially prepared surface, and strike-anywhere matches, for which any suitably frictional surface can be used. Some match-like compositions, known as electric matches, are ignited electrically and do not make use of heat from friction.
Historically, the term match referred to lengths of cord (later cambric) impregnated with chemicals, and allowed to burn continuously. These were used to light fires and fire guns (see matchlock) and cannons (see linstock). Such matches were characterised by their burning speed i.e. quick match and slow match. Depending on its formulation, a slow match burns at a rate of around 30 cm (1 ft) per hour and a quick match at 4 to 60 centimetres (1.6 to 23.6 in) per minute.
The modern equivalent of this sort of match is the simple fuse, still used in pyrotechnics to obtain a controlled time delay before ignition. The original meaning of the word still persists in some pyrotechnics terms, such as black match (a black-powder-impregnated fuse) and Bengal match (a firework akin to sparklers producing a relatively long-burning, coloured flame). But, when friction matches became commonplace, they became the main object meant by the term.
A note in the text Cho Keng Lu, written in 1366, describes a sulfur match, small sticks of pinewood impregnated with sulfur, used in China by "impoverished court ladies" in AD 577 during the conquest of Northern Qi. During the Five Dynasties and Ten Kingdoms (AD 907–960), a book called the Records of the Unworldly and the Strange written by Chinese author Tao Gu in about 950 stated:
If there occurs an emergency at night it may take some time to make a light to light a lamp. But an ingenious man devised the system of impregnating little sticks of pinewood with sulfur and storing them ready for use. At the slightest touch of fire they burst into flame. One gets a little flame like an ear of corn. This marvellous thing was formerly called a "light-bringing slave", but afterwards when it became an article of commerce its name was changed to 'fire inch-stick'.
Another text, Wu Lin Chiu Shih, dated from 1270 AD, lists sulphur matches as something that was sold in the markets of Hangzhou, around the time of Marco Polo's visit. The matches were known as fa chu or tshui erh.
The chemical match
Prior to the use of matches, fires were sometimes lit using a burning glass (a lens) to focus the sun on tinder, a method that could only work on sunny days. Another, more common method was igniting tinder with sparks produced by striking flint and steel, or by sharply increasing air pressure in a fire piston. Early work had been done by alchemist Hennig Brandt, who discovered the flammable nature of phosphorus in 1669. Others, including Robert Boyle and his assistant, Godfrey Haukweicz, continued these experiments in the 1680s with phosphorus and sulfur, but their efforts did not produce practical and inexpensive methods for generating fires.
Smoking tobacco was lit a number of different ways. One was use of a spill, which was a thin object like a straw, rolled paper, or thin candle, which would be lit from a nearby fire and then used to light the pipe or cigar, often kept near the fireplace in a spill vase. Another was to use a striker, a tool that looked like scissors, but with flint on one "blade" and steel on the other. These would be rubbed together, producing sparks. If neither of these were available, one could use ember tongs to pick up a coal from a fire and light the tobacco.
The first modern, self-igniting match was invented in 1805 by Jean Chancel, assistant to Professor Louis Jacques Thénard of Paris. The head of the match consisted of a mixture of potassium chlorate, sulfur, sugar, and rubber. The match was ignited by dipping its tip in a small asbestos bottle filled with sulfuric acid. This kind of match was expensive and its usage was dangerous, so Chancel's matches did not become common.
This approach to match making was refined in the following decades, culminating with the 'Promethean Match', patented by Samuel Jones of London in 1828. His match consisted of a small glass capsule containing a chemical composition of sulfuric acid coloured with indigo and coated on the exterior with potassium chlorate, wrapped up in a roll of paper. Immediate ignition was caused by crushing the capsule with a pair of pliers.
In London, similar matches meant for lighting cigars were introduced in 1849 by Heurtner who had a shop called the Lighthouse in the Strand. One version that he sold was called "Euperion" (sometimes "Empyrion") which was popular for kitchen use and nicknamed as "Hugh Perry" while another meant for outdoor use was called a "Vesuvian". The Vesuvians or "flamers" were designed to work out of doors. The head was large and contained niter, charcoal and wood dust, and had a phosphorus tip. The handle was large and made of hardwood so as to burn vigorously and last for a while. Some even had glass stems. Both Vesuvians and Prometheans had a bulb of sulfuric acid at the tip which had to be broken to start the reaction.
In 1832, William Newton patented the "wax vesta" in England. It consisted of a wax stem that embedded cotton threads and had a tip of phosphorus. Variants known as "candle matches" were made by Savaresse and Merckel in 1836. John Hucks Stevens also patented a safety version of the friction match in 1839.
The friction match
Chemical matches were unable to make the leap into mass production, due to the expense, their cumbersome nature and inherent danger. An alternative method was to produce the ignition through friction produced by rubbing two rough surfaces together. An early example was made by François Derosne in 1816. His crude match was called a briquet phosphorique and it used a sulfur-tipped match to scrape inside a tube coated internally with phosphorus. It was both inconvenient and unsafe.
The first successful friction match was invented in 1826 by English chemist John Walker, a chemist and druggist from Stockton-on-Tees. He developed a keen interest in trying to find a means of obtaining fire easily. Several chemical mixtures were already known which would ignite by a sudden explosion, but it had not been found possible to transmit the flame to a slow-burning substance like wood. While Walker was preparing a lighting mixture on one occasion, a match which had been dipped in it took fire by an accidental friction upon the hearth. He at once appreciated the practical value of the discovery, and started making friction matches. They consisted of wooden splints or sticks of cardboard coated with sulphur and tipped with a mixture of sulphide of antimony, chlorate of potash, and gum, the sulphur serving to communicate the flame to the wood.
The price of a box of 50 matches was one shilling. With each box was supplied a piece of sandpaper, folded double, through which the match had to be drawn to ignite it. He named the matches "Congreves" in honour of the inventor and rocket pioneer, Sir William Congreve. He did not divulge the exact composition of his matches. Between 1827 and 1829, Walker made about 168 sales of his matches. It was however dangerous and flaming balls sometimes fell to the floor burning carpets and dresses, leading to their ban in France and Germany. Walker either did not consider his invention important enough to patent or neglected it. In order for the splints to catch fire, they were often treated with sulfur and the odor was improved by the addition of camphor.
In 1829, Scots inventor Sir Isaac Holden invented an improved version of Walker's match and demonstrated it to his class at Castle Academy in Reading, Berkshire. Holden did not patent his invention and claimed that one of his pupils wrote to his father Samuel Jones, a chemist in London who commercialised his process. A version of Holden's match was patented by Samuel Jones, and these were sold as lucifer matches. These early matches had a number of problems - an initial violent reaction, an unsteady flame and unpleasant odor and fumes. Lucifers could ignite explosively, sometimes throwing sparks a considerable distance. Lucifers were manufactured in the United States by Ezekial Byam. The term "lucifer" persisted as slang in the 20th century (for example in the First World War song Pack Up Your Troubles) and in the Netherlands and Belgium today matches are still called lucifers (in Dutch).
Lucifers were however quickly replaced after the discovery in 1830 by Frenchman Charles Sauria who substituted the antimony sulfide with white phosphorus. These new phosphorus matches had to be kept in airtight metal boxes but became popular. In England, these phosphorus matches were called "Congreves" after Sir William Congreve while they went by the name of loco foco in the United States. The earliest American patent for the phosphorus friction match was granted in 1836 to Alonzo Dwight Phillips of Springfield, Massachusetts.
From 1830 to 1890, the composition of these matches remained largely unchanged, although some improvements were made. In 1843 William Ashgard replaced the sulfur with beeswax, reducing the pungency of the fumes. This was replaced by paraffin in 1862 by Charles W. Smith, resulting in what were called "parlor matches". From 1870 the end of the splint was fireproofed by impregnation with fire-retardant chemicals such as alum, sodium silicate, and other salts resulting in what was commonly called a "drunkard's match" that prevented the accidental burning of the user's fingers. Other advances were made for the mass manufacture of matches. Early matches were made from blocks of woods with cuts separating the splints but leaving their bases attached. Later versions were made in the form of thin combs. The splints would be broken away from the comb when required.
A noiseless match was invented in 1836 by the Hungarian János Irinyi, who was a student of chemistry. An unsuccessful experiment by his professor, Meissner, gave Irinyi the idea to replace potassium chlorate with lead dioxide in the head of the phosphorus match. He liquefied phosphorus in warm water and shook it in a glass vial, until it became granulated. He mixed the phosphorus with lead and gum arabic, poured the paste-like mass into a jar, and dipped the pine sticks into the mixture and let them dry. When he tried them that evening, all of them lit evenly. Irinyi thus invented the noiseless match. He sold the invention to István Rómer, a match manufacturer. Rómer, a Hungarian pharmacist living in Vienna, bought the invention and production rights from Irinyi for 60 forints (about 22.5 oz t of silver). Rómer became rich and Irinyi went on to publish articles and a textbook on chemistry, and founded several match factories.
Replacement of white phosphorus
Those involved in the manufacture of the new phosphorus matches were afflicted with phossy jaw and other bone disorders, and there was enough white phosphorus in one pack to kill a person. Deaths and suicides from eating the heads of matches became frequent. The earliest report of phosphorus necrosis was made in 1845 by Lorinser in Vienna, and a New York surgeon published a pamphlet with notes on nine cases.
The conditions of working class women at the Bryant & May factories led to a strike in 1888. The strike was focused on the severe health complications of working with white phosphorus, such as phossy jaw. Social activist Annie Besant published an article in her halfpenny weekly paper "The Link" on 23 June 1888. A strike fund was set up and some newspapers collected donations from readers. The women and girls also solicited contributions. Members of the Fabian Society including George Bernard Shaw, Sidney Webb and Graham Wallas were involved in the distribution of the cash collected. The strike and negative publicity led to changes being made to limit the health effects of the inhalation of white phosphorus.
Attempts were made to reduce the ill-effects on workers through the introduction of inspections and regulations. Anton Schrötter von Kristelli discovered in 1850 that heating white phosphorus at 250 °C in an inert atmosphere produced a red allotropic form, which did not fume in contact with air. It was suggested that this would make a suitable substitute in match manufacture although it was slightly more expensive. Two French chemists, Henri Savene and Emile David Cahen, proved in 1898 that the addition of phosphorus sesquisulfide meant that the substance was not poisonous, that it could be used in a "strike-anywhere" match, and that the match heads were not explosive.
British company Albright and Wilson, was the first company to produce phosphorus sesquisulfide matches commercially. The company developed a safe means of making commercial quantities of phosphorus sesquisulfide in 1899 and started selling it to match manufacturers. White phosphorus however continued to be used, and its serious effects led many countries to ban its use. Finland prohibited the use of white phosphorus in 1872, followed by Denmark in 1874, France in 1897, Switzerland in 1898, and the Netherlands in 1901. An agreement, the Berne Convention, was reached at Bern, Switzerland, in September 1906, which banned the use of white phosphorus in matches. This required each country to pass laws prohibiting the use of white phosphorus in matches. Great Britain passed a law in 1908 prohibiting its use in matches after 31 December 1910. The United States did not pass a law, but instead placed a "punitive tax" on white phosphorus-based matches, one so high as to render their manufacture financially impractical, in 1913 and Canada banned them in 1914. India and Japan banned them in 1919; China followed, banning them in 1925.
In 1901 Albright and Wilson started making phosphorus sesquisulfide at their Niagara Falls, New York plant for the US market, but American manufacturers continued to use white phosphorus matches. The Niagara Falls plant made them until 1910, when the United States Congress forbade the shipment of white phosphorus matches in interstate commerce.
The safety match
The dangers of white phosphorus in the manufacture of matches led to the development of the "hygienic" or safety match. The major innovation in its development was the use of red phosphorus, not on the head of the match but instead on a specially designed striking surface.
Arthur Albright developed the industrial process for large-scale manufacture of red phosphorus after Schrötter’s discoveries became known. By 1851, his company was producing the substance by heating white phosphorus in a sealed pot at a specific temperature. He exhibited his red phosphorus in 1851, at The Great Exhibition in London.
The idea of creating a specially designed striking surface was developed in 1844 by the Swede Gustaf Erik Pasch. Pasch patented the use of red phosphorus in the striking surface. He found that this could ignite heads that did not need to contain white phosphorus. Johan Edvard and his younger brother Carl Frans Lundström (1823–1917) started a large-scale match industry in Jönköping, Sweden around 1847, but the improved safety match was not introduced until around 1850–55. The Lundström brothers had obtained a sample of red phosphorus matches from Arthur Albright at The Great Exhibition, held at The Crystal Palace in 1851, but had misplaced it and therefore they did not try the matches until just before the Paris Exhibition of 1855 when they found that the matches were still usable. In 1858 their company produced around 12 million match boxes.
The safety of true "safety matches" is derived from the separation of the reactive ingredients between a match head on the end of a paraffin-impregnated splint and the special striking surface (in addition to the safety aspect of replacing the white phosphorus with red phosphorus). The idea for separating the chemicals had been introduced in 1859 in the form of two-headed matches known in France as Alumettes Androgynes. These were sticks with one end made of potassium chlorate and the other of red phosphorus. They had to be broken and the heads rubbed together. There was however a risk of the heads rubbing each other accidentally in their box. Such dangers were removed when the striking surface was moved to the outside of the box. The striking surface on modern matchboxes is typically composed of 25% powdered glass or other abrasive material, 50% red phosphorus, 5% neutralizer, 4% carbon black, and 16% binder; and the match head is typically composed of 45–55% potassium chlorate, with a little sulfur and starch, a neutralizer (ZnO or CaCO
3), 20–40% of siliceous filler, diatomite, and glue. Some heads contain antimony(III) sulfide to make them burn more vigorously. Safety matches ignite due to the extreme reactivity of phosphorus with the potassium chlorate in the match head. When the match is struck the phosphorus and chlorate mix in a small amount forming something akin to the explosive Armstrong's mixture which ignites due to the friction.
The Swedes long held a virtual worldwide monopoly on safety matches, with the industry mainly situated in Jönköping, by 1903 called Jönköpings & Vulcans Tändsticksfabriks AB. In France, they sold the rights to their safety match patent to Coigent Père & Fils of Lyon, but Coigent contested the payment in the French courts, on the basis that the invention was known in Vienna before the Lundström brothers patented it. The British match manufacturer Bryant and May visited Jönköping in 1858 to try to obtain a supply of safety matches, but it was unsuccessful. In 1862 it established its own factory and bought the rights for the British safety match patent from the Lundström brothers.
Varieties of matches today
Friction matches made with white phosphorus as well as those made from phosphorus sesquisulfide can be struck on any suitable surface. They remained particularly popular in the United States even when safety matches had become common in Europe. However, strike anywhere matches are still used today all around the world, including many developing countries. Strike anywhere matches are still widely used today for such uses as camping, outdoor activities, emergency/survival situations, and stocking homemade survival kits.
Safety matches are classified as dangerous goods, "U.N. 1944, Matches, safety". They are not universally forbidden on aircraft; however, they must be declared as dangerous goods and individual airlines or countries may impose tighter restrictions.
Storm matches, also known as lifeboat matches or flare matches, are often included in survival kits. They have a strikeable tip similar to a normal match, but the combustible compound continues down the length of the stick, coating half or more of the entire matchstick. The match also has a waterproof coating (which often makes the match more difficult to light), and often storm matches are longer than standard matches. As a result of the combustible coating, storm matches burn strongly even in strong winds, and can even spontaneously re-ignite after being briefly immersed under water.
- Ivar Kreuger
- Hendrick Lucifer
- London matchgirls strike of 1888
- John Leonard Orr
- Permanent Match
- Swedish Match
- The Little Match Girl
- The Safety Matches
- Vesta case
- Concise Oxford Dictionary (10 ed.). London: Oxford University Press. 1999.
- Sawyer, C. W. (1910). Firearms in American history 1600–1800. p. 5.
- Barnett, E. de Barry (1919). Rideal, Samuel, ed. Explosives. New York: D. Van Nostrand Co. pp. 158, 162–170.
- Whiter W (1825). Etymologicon universale: or, Universal etymological dictionary 2. p. 428.
- Joseph Needham (1 January 1962). Science and Civilization in China: Volume 4, Physics and Physical Technology; Part 1, Physics. Cambridge University Press. pp. 70–71. ISBN 978-0-521-05802-5.
sulphur matches were certainly sold in the markets of Hangchow when Marco Polo was there
- Crass, M. F., Jr. (1941). "A history of the match industry. Part 1". Journal of Chemical Education 18 (3): 116–120. Bibcode:1941JChEd..18..116C. doi:10.1021/ed018p116.
- Carlisle, Rodney (2004). Scientific American Inventions and Discoveries. New Jersey: John Wiley & Sons. p. 275. ISBN 0-471-24410-4.
- Spilling the Whole Story
- Wisniak, Jaime (2005). "Matches—The manufacture of fire" (PDF). Indian Journal of Chemical Technology 12: 369–380.
- Crass, M. F., Jr. (1941). "A history of the match industry. Part 3". Journal of Chemical Education 18 (6): 277–282. Bibcode:1941JChEd..18..277C. doi:10.1021/ed018p277.
- Tomlinson, C. (1898). "The Inventor of Lucifer Matches". Notes and Queries 8 (4): 70–71.
- Stevens, John Hucks (November 16, 1839), U.S. Patent Number 1,414, Improved Friction-Match for Retaining Fire, Entitled Stevens’ "Fusse Cigar-Light"
- Stevens, John Hucks (November 16, 1839), U.S. Patent Number 1,412A, Improvement in the Manufacture of Friction-Matches for Preserving Them From Accidental Ignition
- Encyclopedia Britannica (2012)
- "Walker, John (1781?-1859)". Dictionary of National Biography. London: Smith, Elder & Co. 1885–1900.
- Brewis, W, Parke (1909). "Archaeologia aeliana, or, Miscellaneous tracts relating to antiquity". Archaeologia Aeliana. Third series 6: xix.
- John Wesley Hanson (1900) Wonders of the nineteenth century: a panoramic review of the inventions and discoveries of the past hundred years, W. B. Conkey Publishers, Chicago
- Lewis R. Goldfrank; Neal Flomenbaum (2006). Goldfrank's toxicologic emergencies. McGraw-Hill Professional. pp. 1486–. ISBN 978-0-07-147914-1. Retrieved 19 November 2011.
- "János Irinyi". Hungarian Patent Office. Retrieved 18 March 2008.
- "Development of matches". Encyclopædia Britannica. Retrieved 18 March 2008.
- Hughes, J. P. W; Baron, R.; Buckland, D. H., Cooke, M. A.; Craig, J. D.; Duffield, D. P.; Grosart, A. W.; Parkes, P. W. J.; & Porter, A. (1962). "Phosphorus Necrosis of the Jaw: A Present-day Study: With Clinical and Biochemical Studies". Brit. J. Industr. Med. 19 (2): 83–99. doi:10.1136/oem.19.2.83. PMC 1038164. PMID 14449812.
- Crass, M. F., Jr. (1941). "A history of the match industry. Part 9" (PDF). Journal of Chemical Education 18 (9): 428–431. Bibcode:1941JChEd..18..428C. doi:10.1021/ed018p428.
- Oliver, Thomas (1906). Industrial disease due to certain poisonous fumes or gases. Archives of the Public Health Laboratory 1 (Manchester University Press). pp. 1–21.
- "Matchgirls Strike". Spartacus Educational. Retrieved 2006-05-19.
- "White slavery in London" The Link, Issue no. 21 (via Tower Hamlets' Local History Library and Archives)
- Raw p.137
- Kohn, Moritz (1944). "The discovery of red phosphorus (1847) by Anton von Schrötter (1802–1875)" (PDF). J. Chem. Educ. 21 (11): 522, 554. Bibcode:1944JChEd..21..522K. doi:10.1021/ed021p522.
- Threfall (1951), "Chapter IX: The Second generation: 1880–1915: part II: The Private Limited Company
- Threfall (1951)
- Crass, M. F., Jr. (1941). "A history of the match industry. Part 5" (PDF). J. Chemical Education 18 (7): 316–319. Bibcode:1941JChEd..18..316C. doi:10.1021/ed018p316.
- Charnovitz, Steve (1987). "The Influence of International Labour Standards on the World Trading Regime. A Historical Overview". International Labour Review 126 (5): 565, 571.
- Donalda Charron and the E.B. Eddy Match Company. National Capital Commission. museevirtuel-virtualmuseum.ca
- Threfall (1951), Chapter V: "The Foundations, 1855–56: the phosphorus retort"
- "Fire". Retrieved 19 November 2011.
- Threfall (1951), Appendix A to Chapter V: "The Match Industry"
- Staff (March 10, 2012). "Legality Of Strike Anywhere Matches Is Up For Debate". PRWeb.com. Retrieved 16 July 2013.
- McCafferty, Keith (November 10, 2009). "Strike Anywhere: The Best Matches for Survival Situations". Field & Stream. Retrieved 16 July 2013.
- IATA (2007). Dangerous Goods Regulations: Effective 1 January – 31 December 2007. Produced in consultation with ICAO. Montreal: International Air Transport Association. ISBN 92-9195-780-1.
- Threlfall, Richard E. (1951). The Story of 100 Years of Phosphorus Making: 1851–1951. Oldbury: Albright & Wilson Ltd.
- Beaver, Patrick (1985). The Match Makers: The Story of Bryant & May. London: Henry Melland Limited. ISBN 0-907929-11-7
- Emsley, John (2000). The Shocking History of Phosphorus: A Biography of the Devil's Element. Basingstoke: Macmillan Publishing. ISBN 0-333-76638-5
- Steele, H. Thomas (1987). Close Cover Before Striking: The Golden Age of Matchbook Art. Abeville Press
|Look up match in Wiktionary, the free dictionary.|
|Wikimedia Commons has media related to Matches.|
- "History of Chemical Matches". Chemistry.about.com.
- "The History of Matches". Inventors.about.com.
- "Making 125,000 Matches An Hour", August 1946, Popular Science article on the modern mass production of wooden stem matches
- "History of matchbooks". Matchcovers.com/first100.htm.
- "The Rathkamp Matchcover Society". matchcover.org.library.thinkquest.org/23062/match.htm
- "Lighting a Match", Royal Institution video on the ignition process