Brass is an alloy of copper (Cu) and zinc (Zn), in proportions which can be varied to achieve varying mechanical, electrical, and chemical properties. It is a substitutional alloy: atoms of the two constituents may replace each other within the same crystal structure.
Brass is similar to bronze, another alloy containing copper that uses tin instead of zinc. Both bronze and brass also may include small proportions of a range of other elements including arsenic (As), lead (Pb), phosphorus (P), aluminum (Al), manganese (Mn), and silicon (Si). Historically, the distinction between the two alloys has been less consistent and clear, and modern practice in museums and archaeology increasingly avoids both terms for historical objects in favor of the more general "copper alloy".
Brass has long been a popular material for decoration due to its bright, gold-like appearance; being used for drawer pulls and doorknobs. It has also been widely used to make utensils due to properties such as having a low melting point, high workability (both with hand tools and with modern turning and milling machines), durability, and electrical and thermal conductivity.
Brass is still commonly used in applications where corrosion resistance and low friction are required, such as locks, hinges, gears, bearings, ammunition casings, zippers, plumbing, hose couplings, valves, and electrical plugs and sockets. It is used extensively for musical instruments such as horns and bells, and also used as a substitute for copper in making costume jewelry, fashion jewelry, and other imitation jewelry. The composition of brass, generally 66% copper and 34% zinc, makes it a favorable substitute for copper based jewelry, as it exhibits greater resistance to corrosion. Brass is not suitable for such items as boat propellers because the zinc reacts with minerals in salt water, leaving porous copper behind. The tin in bronze will not react with these minerals.
Brass is often used in situations in which it is important that sparks not be struck, such as in fittings and tools used near flammable or explosive materials.
Brass is more malleable than bronze or zinc. The relatively low melting point of brass (900 to 940 °C, 1,650 to 1,720 °F, depending on composition) and its flow characteristics make it a relatively easy material to cast. By varying the proportions of copper and zinc, the properties of the brass can be changed, allowing hard and soft brasses. The density of brass is 8.4 to 8.73 g/cm3 (0.303 to 0.315 lb/cu in).
Today, almost 90% of all brass alloys are recycled. Because brass is not ferromagnetic, it can be separated from ferrous scrap by passing the scrap near a powerful magnet. Brass scrap is collected and transported to the foundry, where it is melted and recast into billets. Billets are heated and extruded into the desired form and size. The general softness of brass means that it can often be machined without the use of cutting fluid, though there are exceptions to this.
Aluminium makes brass stronger and more corrosion-resistant. Aluminium also causes a highly beneficial hard layer of aluminium oxide (Al2O3) to be formed on the surface that is thin, transparent, and self-healing. Tin has a similar effect and finds its use especially in seawater applications (naval brasses). Combinations of iron, aluminium, silicon, and manganese make brass wear- and tear-resistant. Notably, the addition of as little as 1% iron to a brass alloy will result in an alloy with a noticeable magnetic attraction.
Brass will corrode in the presence of moisture, chlorides, acetates, ammonia, and certain acids. This often happens when the copper reacts with sulfur to form a brown and eventually black surface layer of copper sulfide which, if regularly exposed to slightly acidic water such as urban rainwater, can then oxidize in air to form a patina of green-blue copper sulfate.[clarification needed] Depending on how the sulfide/sulfate layer was formed, this layer may protect the underlying brass from further damage.
Although copper and zinc have a large difference in electrical potential, the resulting brass alloy does not experience internalized galvanic corrosion because of the absence of a corrosive environment within the mixture. However, if brass is placed in contact with a more noble metal such as silver or gold in such an environment, the brass will corrode galvanically; conversely, if brass is in contact with a less-noble metal such as zinc or iron, the less noble metal will corrode and the brass will be protected.
To enhance the machinability of brass, lead is often added in concentrations of around 2%. Since lead has a lower melting point than the other constituents of the brass, it tends to migrate towards the grain boundaries in the form of globules as it cools from casting. The pattern the globules form on the surface of the brass increases the available lead surface area which in turn affects the degree of leaching. In addition, cutting operations can smear the lead globules over the surface. These effects can lead to significant lead leaching from brasses of comparatively low lead content.
In October 1999, the California State Attorney General sued 13 key manufacturers and distributors over lead content. In laboratory tests, state researchers found the average brass key, new or old, exceeded the California Proposition 65 limits by an average factor of 19, assuming handling twice a day. In April 2001 manufacturers agreed to reduce lead content to 1.5%, or face a requirement to warn consumers about lead content. Keys plated with other metals are not affected by the settlement, and may continue to use brass alloys with a higher percentage of lead content.
Also in California, lead-free materials must be used for "each component that comes into contact with the wetted surface of pipes and pipe fittings, plumbing fittings and fixtures". On 01 January 2010, the maximum amount of lead in "lead-free brass" in California was reduced from 4% to 0.25% lead.
Corrosion-resistant brass for harsh environments
Dezincification-resistant (DZR or DR) brasses, sometimes referred to as CR (corrosion resistant) brasses, are used where there is a large corrosion risk and where normal brasses do not meet the requirements. Applications with high water temperatures, chlorides present or deviating water qualities (soft water) play a role. DZR-brass is excellent in water boiler systems. This brass alloy must be produced with great care, with special attention placed on a balanced composition and proper production temperatures and parameters to avoid long-term failures.
An example of DZR brass is the C352 brass, with about 30% zinc, 61–63% copper, 1.7–2.8% lead, and 0.02–0.15% arsenic. The lead and arsenic significantly suppress the zinc loss.
"Red brasses", a family of alloys with high copper proportion and generally less than 15% zinc, are more resistant to zinc loss. One of the metals called "red brass" is 85% copper, 5% tin, 5% lead, and 5% zinc. Copper alloy C23000, which is also known as "red brass", contains 84–86% copper, 0.05% each iron and lead, with the balance being zinc.
Another such material is gunmetal, from the family of red brasses. Gunmetal alloys contain roughly 88% copper, 8-10% tin, and 2-4% zinc. Lead can be added for ease of machining or for bearing alloys.
"Naval brass", for use in seawater, contains 40% zinc but also 1% tin. The tin addition suppresses zinc leaching.
Use in musical instruments
The high malleability and workability, relatively good resistance to corrosion, and traditionally attributed acoustic properties of brass, have made it the usual metal of choice for construction of musical instruments whose acoustic resonators consist of long, relatively narrow tubing, often folded or coiled for compactness; silver and its alloys, and even gold, have been used for the same reasons, but brass is the most economical choice. Collectively known as brass instruments, these include the trombone, tuba, trumpet, cornet, baritone horn, euphonium, tenor horn, and French horn, and many other "horns", many in variously-sized families, such as the saxhorns.
Other wind instruments may be constructed of brass or other metals, and indeed most modern student-model flutes and piccolos are made of some variety of brass, usually a cupronickel alloy similar to nickel silver (also known as German silver). Clarinets, especially low clarinets such as the contrabass and subcontrabass, are sometimes made of metal because of limited supplies of the dense, fine-grained tropical hardwoods traditionally preferred for smaller woodwinds. For the same reason, some low clarinets, bassoons and contrabassoons feature a hybrid construction, with long, straight sections of wood, and curved joints, neck, and/or bell of metal. The use of metal also avoids the risks of exposing wooden instruments to changes in temperature or humidity, which can cause sudden cracking. Even though the saxophones and sarrusophones are classified as woodwind instruments, they are normally made of brass for similar reasons, and because their wide, conical bores and thin-walled bodies are more easily and efficiently made by forming sheet metal than by machining wood.
The keywork of most modern woodwinds, including wooden-bodied instruments, is also usually made of an alloy such as nickel silver. Such alloys are stiffer and more durable than the brass used to construct the instrument bodies, but still workable with simple hand tools—a boon to quick repairs. The mouthpieces of both brass instruments and, less commonly, woodwind instruments are often made of brass among other metals as well.
Next to the brass instruments, the most notable use of brass in music is in various percussion instruments, most notably cymbals, gongs, and orchestral (tubular) bells (large "church" bells are normally made of bronze). Small handbells and "jingle bell" are also commonly made of brass.
The harmonica is a free reed aerophone, also often made from brass. In organ pipes of the reed family, brass strips (called tongues) are used as the reeds, which beat against the shallot (or beat "through" the shallot in the case of a "free" reed). Although not part of the brass section, snare drums are also sometimes made of brass. Some parts on electric guitars are also made from brass, especially inertia blocks on tremolo systems for its tonal properties, and for string nuts and saddles for both tonal properties and its low friction.
Germicidal and antimicrobial applications
The bactericidal properties of brass have been observed for centuries, particularly in marine environments where it prevents biofouling. Depending upon the type and concentration of pathogens and the medium they are in, brass kills these microorganisms within a few minutes to hours of contact.
A large number of independent studies confirm this antimicrobial effect, even against antibiotic-resistant bacteria such as MRSA and VRSA. The mechanisms of antimicrobial action by copper and its alloys, including brass, are a subject of intense and ongoing investigation.
Brass is susceptible to stress corrosion cracking, especially from ammonia or substances containing or releasing ammonia. The problem is sometimes known as season cracking after it was first discovered in brass cartridges used for rifle ammunition during the 1920s in the British Indian Army. The problem was caused by high residual stresses from cold forming of the cases during manufacture, together with chemical attack from traces of ammonia in the atmosphere. The cartridges were stored in stables and the ammonia concentration rose during the hot summer months, thus initiating brittle cracks. The problem was resolved by annealing the cases, and storing the cartridges elsewhere.
|Class||Proportion by weight (%)||Notes|
|Alpha brasses||> 65||< 35||Alpha brasses are malleable, can be worked cold, and are used in pressing, forging, or similar applications. They contain only one phase, with face-centered cubic crystal structure. With their high proportion of copper, these brasses have a more golden hue than others. The alpha phase is a substitution solid solution of zinc in copper. It is close in properties to copper, tough, strong, and somewhat difficult to machine. Best formability is with 32% of zinc. Corrosion-resistant red brasses, with 15% of zinc or less, belong here.|
|Alpha-beta brasses||55–65||35–45||Also called duplex brasses, these are suited for hot working. They contain both α and β' phases; the β'-phase is ordered body-centered cubic, with zinc atoms in the center of the cubes, and is harder and stronger than α. Alpha-beta brasses are usually worked hot. The higher proportion of zinc means these brasses are brighter than alpha brasses. At 45% of zinc the alloy has the highest strength.|
|Beta brasses||50–55||45–50||Beta brasses can only be worked hot, and are harder, stronger, and suitable for casting. The high zinc-low copper content means these are some of the brightest and least-golden of the common brasses.|
|Gamma brasses||33–39||61–67||There are also Ag-Zn and Au-Zn gamma brasses, Ag 30–50%, Au 41%. The gamma phase is a cubic-lattice intermetallic compound, Cu5Zn8.|
|White brass||< 50||> 50||These are too brittle for general use. The term may also refer to certain types of nickel silver alloys as well as Cu-Zn-Sn alloys with high proportions (typically 40%+) of tin and/or zinc, as well as predominantly zinc casting alloys with copper additives. These have virtually no yellow coloring at all, and instead have a much more silvery appearance.|
Other phases than α, β and γ are ε, a hexagonal intermetallic CuZn3, and η, a solid solution of copper in zinc.
|Alloy name||Proportion by weight (%)||Other||Notes|
|Admiralty brass||69||30||1||Tin inhibits loss of zinc in many environments.|
|Aich's alloy||60.66||36.58||1.02||1.74% iron||Designed for use in marine service owing to its corrosion resistance, hardness and toughness. A characteristic application is to the protection of ships' bottoms, but more modern methods of cathodic protection have rendered its use less common. Its appearance resembles that of gold.|
|Aluminium brass||77.5||20.5||2% aluminum||Aluminium improves corrosion resistance. It is used for heat exchanger and condenser tubes.|
|Arsenical brass||Arsenic; frequently aluminum||Used for boiler fireboxes.|
|Cartridge brass (C260)||70||30||—||≤ 0.07||Good cold working properties. Used for ammunition cases, plumbing, and hardware.|
|Common brass||63||37||Also called rivet brass. Cheap and standard for cold working.|
|DZR brass||Arsenic||Dezincification resistant brass with a small percentage of arsenic.|
|Delta metal||55||41–43||1–3% iron with the balance consisting of various other metals.||The proportions used make the material harder and suitable for valves and bearings.|
|Free machining brass (C360)||61.5||35.5||2.5–3.7||0.35% iron||Also called 360 or C360 brass. High machinability.|
|Gilding metal||95||5||Softest type of brass commonly available. Gilding metal is typically used for ammunition bullet "jackets"; e.g., full metal jacket bullets. Almost red in color.|
|High brass||65||35||Has a high tensile strength and is used for springs, screws, and rivets.|
|Leaded brass||> 0||An alpha-beta brass with an addition of lead for improved machinability.|
|Lead-free brass||< 0.25||Defined by California Assembly Bill AB 1953 contains "not more than 0.25 percent lead content". Prior upper limit was 4%.|
|Low brass||80||20||Light golden color, very ductile; used for flexible metal hoses and metal bellows.|
|Manganese brass||70||29||1.3% manganese||Most notably used in making golden dollar coins in the United States.|
|Muntz metal||60||40||Traces of iron||Used as a lining on boats.|
|Naval brass||59||40||1||Similar to admiralty brass. Also known as Tobin bronze.|
|Nickel brass||70–76||20–24.5||4–5.5% nickel||The outer ring of the bi-metallic one pound and two pound sterling coins and the one euro coin, plus the centre part of the two euro coin. Formerly used for the round one pound coin.|
|Nordic gold||89||5||1||5% aluminum||Used in 10, 20, and 50 cents euro coins.|
|Orichalcum||75-80||15-20||Trace||Trace amounts of nickel and iron||Determined from 39 ingots recovered from an ancient shipwreck in Gela, Sicily.|
|Prince's metal||75||25||A type of alpha brass. Due to its yellow color, it is used as an imitation of gold. Also called Prince Rupert's metal, the alloy was named after Prince Rupert of the Rhine.|
|Red brass, Rose brass (C230)||85||5||5||5||Both an American term for the copper-zinc-tin alloy known as gunmetal, and an alloy which is considered both a brass and a bronze. Red brass is also an alternative name for copper alloy C23000, which is composed of 14–16% zinc, a minimum 0.05% iron and minimum 0.07% lead content, and the remainder copper. It may also refer to ounce metal, another copper-zinc-tin alloy.|
|Rich low brass, Tombac||5–20||Often used in jewelry applications.|
|Silicon tombac||80||16||4% silicon||Used as an alternative for investment cast steel parts.|
|Tonval brass||> 0||Also called CW617N or CZ122 or OT58. It is not recommended for sea water use, being susceptible to dezincification.|
|Yellow brass||67||33||An American term for 33% zinc brass.|
Although forms of brass have been in use since prehistory, its true nature as a copper-zinc alloy was not understood until the post-medieval period because the zinc vapor which reacted with copper to make brass was not recognised as a metal. The King James Bible makes many references to "brass" to translate "nechosheth" (bronze or copper) from Hebrew to English. The Shakespearean English use of the word 'brass' can mean any bronze alloy, or copper, an even less precise definition than the modern one. The earliest brasses may have been natural alloys made by smelting zinc-rich copper ores. By the Roman period brass was being deliberately produced from metallic copper and zinc minerals using the cementation process, the product of which was calamine brass, and variations on this method continued until the mid-19th century. It was eventually replaced by speltering, the direct alloying of copper and zinc metal which was introduced to Europe in the 16th century.
Early copper-zinc alloys
In West Asia and the Eastern Mediterranean early copper-zinc alloys are now known in small numbers from a number of 3rd millennium BC sites in the Aegean, Iraq, the United Arab Emirates, Kalmykia, Turkmenistan and Georgia and from 2nd millennium BC sites in West India, Uzbekistan, Iran, Syria, Iraq and Canaan. Isolated examples of copper-zinc alloys are known in China from the 1st century AD, long after bronze was widely used.
The compositions of these early "brass" objects are highly variable and most have zinc contents of between 5% and 15% wt which is lower than in brass produced by cementation. These may be "natural alloys" manufactured by smelting zinc rich copper ores in redox conditions. Many have similar tin contents to contemporary bronze artefacts and it is possible that some copper-zinc alloys were accidental and perhaps not even distinguished from copper. However the large number of copper-zinc alloys now known suggests that at least some were deliberately manufactured and many have zinc contents of more than 12% wt which would have resulted in a distinctive golden color.
By the 8th–7th century BC Assyrian cuneiform tablets mention the exploitation of the "copper of the mountains" and this may refer to "natural" brass. "Oreikhalkon" (mountain copper), the Ancient Greek translation of this term, was later adapted to the Latin aurichalcum meaning "golden copper" which became the standard term for brass. In the 4th century BC Plato knew orichalkos as rare and nearly as valuable as gold and Pliny describes how aurichalcum had come from Cypriot ore deposits which had been exhausted by the 1st century AD. X-ray fluorescence analysis of 39 orichalcum ingots recovered from a 2,600-year-old shipwreck off Sicily found them to be an alloy made with 75–80% copper, 15–20% zinc and small percentages of nickel, lead and iron.
During the later part of first millennium BC the use of brass spread across a wide geographical area from United Kingdom  and Spain  in the west to Iran, and India in the east. This seems to have been encouraged by exports and influence from the Middle East and eastern Mediterranean where deliberate production of brass from metallic copper and zinc ores had been introduced. The 4th century BC writer Theopompus, quoted by Strabo, describes how heating earth from Andeira in Turkey produced "droplets of false silver", probably metallic zinc, which could be used to turn copper into oreichalkos. In the 1st century BC the Greek Dioscorides seems to have recognised a link between zinc minerals and brass describing how Cadmia (zinc oxide) was found on the walls of furnaces used to heat either zinc ore or copper and explaining that it can then be used to make brass.
By the first century BC brass was available in sufficient supply to use as coinage in Phrygia and Bithynia, and after the Augustan currency reform of 23 BC it was also used to make Roman dupondii and sestertii. The uniform use of brass for coinage and military equipment across the Roman world may indicate a degree of state involvement in the industry, and brass even seems to have been deliberately boycotted by Jewish communities in Palestine because of its association with Roman authority.
Brass was produced by the cementation process where copper and zinc ore are heated together until zinc vapor is produced which reacts with the copper. There is good archaeological evidence for this process and crucibles used to produce brass by cementation have been found on Roman period sites including Xanten and Nidda in Germany , Lyon in France  and at a number of sites in Britain. They vary in size from tiny acorn sized to large amphorae like vessels but all have elevated levels of zinc on the interior and are lidded. They show no signs of slag or metal prills suggesting that zinc minerals were heated to produce zinc vapor which reacted with metallic copper in a solid state reaction. The fabric of these crucibles is porous, probably designed to prevent a buildup of pressure, and many have small holes in the lids which may be designed to release pressure or to add additional zinc minerals near the end of the process. Dioscorides mentioned that zinc minerals were used for both the working and finishing of brass, perhaps suggesting secondary additions.
Brass made during the early Roman period seems to have varied between 20% and 28% wt zinc. The high content of zinc in coinage and brass objects declined after the first century AD and it has been suggested that this reflects zinc loss during recycling and thus an interruption in the production of new brass. However it is now thought this was probably a deliberate change in composition and overall the use of brass increases over this period making up around 40% of all copper alloys used in the Roman world by the 4th century AD.
Little is known about the production of brass during the centuries immediately after the collapse of the Roman Empire. Disruption in the trade of tin for bronze from Western Europe may have contributed to the increasing popularity of brass in the east and by the 6th–7th centuries AD over 90% of copper alloy artefacts from Egypt were made of brass. However other alloys such as low tin bronze were also used and they vary depending on local cultural attitudes, the purpose of the metal and access to zinc, especially between the Islamic and Byzantine world. Conversely the use of true brass seems to have declined in Western Europe during this period in favour of gunmetals and other mixed alloys but by about 1000 brass artefacts are found in Scandinavian graves in Scotland, brass was being used in the manufacture of coins in Northumbria and there is archaeological and historical evidence for the production of calamine brass in Germany and the Low Countries, areas rich in calamine ore.
These places would remain important centres of brass making throughout the medieval period, especially Dinant. Brass objects are still collectively known as dinanderie in French. The baptismal font at St Bartholomew's Church, Liège in modern Belgium (before 1117) is an outstanding masterpiece of Romanesque brass casting, though also often described as bronze. The metal of the early 12th-century Gloucester Candlestick is unusual even by medieval standards in being a mixture of copper, zinc, tin, lead, nickel, iron, antimony and arsenic with an unusually large amount of silver, ranging from 22.5% in the base to 5.76% in the pan below the candle. The proportions of this mixture may suggest that the candlestick was made from a hoard of old coins, probably Late Roman. Latten is a term for decorative borders and similar objects cut from sheet metal, whether of brass or bronze. Aquamaniles were typically made in brass in both the European and Islamic worlds.
The cementation process continued to be used but literary sources from both Europe and the Islamic world seem to describe variants of a higher temperature liquid process which took place in open-topped crucibles. Islamic cementation seems to have used zinc oxide known as tutiya or tutty rather than zinc ores for brass-making, resulting in a metal with lower iron impurities. A number of Islamic writers and the 13th century Italian Marco Polo describe how this was obtained by sublimation from zinc ores and condensed onto clay or iron bars, archaeological examples of which have been identified at Kush in Iran. It could then be used for brass making or medicinal purposes. In 10th century Yemen al-Hamdani described how spreading al-iglimiya, probably zinc oxide, onto the surface of molten copper produced tutiya vapor which then reacted with the metal. The 13th century Iranian writer al-Kashani describes a more complex process whereby tutiya was mixed with raisins and gently roasted before being added to the surface of the molten metal. A temporary lid was added at this point presumably to minimise the escape of zinc vapor.
In Europe a similar liquid process in open-topped crucibles took place which was probably less efficient than the Roman process and the use of the term tutty by Albertus Magnus in the 13th century suggests influence from Islamic technology. The 12th century German monk Theophilus described how preheated crucibles were one sixth filled with powdered calamine and charcoal then topped up with copper and charcoal before being melted, stirred then filled again. The final product was cast, then again melted with calamine. It has been suggested that this second melting may have taken place at a lower temperature to allow more zinc to be absorbed. Albertus Magnus noted that the "power" of both calamine and tutty could evaporate and described how the addition of powdered glass could create a film to bind it to the metal. German brass making crucibles are known from Dortmund dating to the 10th century AD and from Soest and Schwerte in Westphalia dating to around the 13th century confirm Theophilus' account, as they are open-topped, although ceramic discs from Soest may have served as loose lids which may have been used to reduce zinc evaporation, and have slag on the interior resulting from a liquid process.
Some of the most famous objects in African art are the lost wax castings of West Africa, mostly from what is now Nigeria, produced first by the Kingdom of Ife and then the Benin Empire. Though normally described as "bronzes", the Benin Bronzes, now mostly in the British Museum and other Western collections, and the large portrait heads such as the Bronze Head from Ife of "heavily leaded zinc-brass" and the Bronze Head of Queen Idia, both also British Museum, are better described as brass, though of variable compositions. Work in brass or bronze continued to be important in Benin art and other West African traditions such as Akan goldweights, where the metal was regarded as a more valuable material than in Europe.
Renaissance and post-medieval Europe
The Renaissance saw important changes to both the theory and practice of brassmaking in Europe. By the 15th century there is evidence for the renewed use of lidded cementation crucibles at Zwickau in Germany. These large crucibles were capable of producing c.20 kg of brass. There are traces of slag and pieces of metal on the interior. Their irregular composition suggests that this was a lower temperature, not entirely liquid, process. The crucible lids had small holes which were blocked with clay plugs near the end of the process presumably to maximise zinc absorption in the final stages. Triangular crucibles were then used to melt the brass for casting.
16th-century technical writers such as Biringuccio, Ercker and Agricola described a variety of cementation brass making techniques and came closer to understanding the true nature of the process noting that copper became heavier as it changed to brass and that it became more golden as additional calamine was added. Zinc metal was also becoming more commonplace. By 1513 metallic zinc ingots from India and China were arriving in London and pellets of zinc condensed in furnace flues at the Rammelsberg in Germany were exploited for cementation brass making from around 1550.
Eventually it was discovered that metallic zinc could be alloyed with copper to make brass, a process known as speltering, and by 1657 the German chemist Johann Glauber had recognised that calamine was "nothing else but unmeltable zinc" and that zinc was a "half ripe metal". However some earlier high zinc, low iron brasses such as the 1530 Wightman brass memorial plaque from England may have been made by alloying copper with zinc and include traces of cadmium similar to those found in some zinc ingots from China.
However, the cementation process was not abandoned, and as late as the early 19th century there are descriptions of solid-state cementation in a domed furnace at around 900–950 °C and lasting up to 10 hours. The European brass industry continued to flourish into the post medieval period buoyed by innovations such as the 16th century introduction of water powered hammers for the production of battery wares. By 1559 the Germany city of Aachen alone was capable of producing 300,000 cwt of brass per year. After several false starts during the 16th and 17th centuries the brass industry was also established in England taking advantage of abundant supplies of cheap copper smelted in the new coal fired reverberatory furnace. In 1723 Bristol brass maker Nehemiah Champion patented the use of granulated copper, produced by pouring molten metal into cold water. This increased the surface area of the copper helping it react and zinc contents of up to 33% wt were reported using this new technique.
In 1738 Nehemiah's son William Champion patented a technique for the first industrial scale distillation of metallic zinc known as distillation per descencum or "the English process". This local zinc was used in speltering and allowed greater control over the zinc content of brass and the production of high-zinc copper alloys which would have been difficult or impossible to produce using cementation, for use in expensive objects such as scientific instruments, clocks, brass buttons and costume jewellery. However Champion continued to use the cheaper calamine cementation method to produce lower-zinc brass and the archaeological remains of bee-hive shaped cementation furnaces have been identified at his works at Warmley. By the mid-to-late 18th century developments in cheaper zinc distillation such as John-Jaques Dony's horizontal furnaces in Belgium and the reduction of tariffs on zinc as well as demand for corrosion-resistant high zinc alloys increased the popularity of speltering and as a result cementation was largely abandoned by the mid-19th century.
- Engineering Designer 30(3): 6–9, May–July 2004
- Machinery Handbook, Industrial Press Inc, New York, Edition 24, p. 501
- Bearings and bearing metals. The Industrial Press. 1921. p. 29. https://archive.org/details/bearingsandbear01unkngoog.
- "copper alloy (Scope note)". https://www.britishmuseum.org/research/search_the_collection_database/term_details.aspx?scopeType=Terms&scopeId=18864. "The term copper alloy should be searched for full retrievals on objects made of bronze or brass. This is because bronze and brass have at times been used interchangeably in the old documentation, and copper alloy is the Broad Term of both. In addition, the public may refer to certain collections by their popular name, such as 'The Benin Bronzes' most of which are actually made of brass"
- "Hand Tools - Non-sparking tools". 2017-12-01. https://www.ccohs.ca/oshanswers/safety_haz/hand_tools/nonsparking.html.
- Walker, Roger. "Mass, Weight, Density or Specific Gravity of Different Metals". Density of Materials. United Kingdom: SImetric.co.uk. http://www.simetric.co.uk/si_metals.htm. "brass – casting, 8400–8700... brass – rolled and drawn, 8430–8730"
- M. F. Ashby; Kara Johnson (2002). Materials and design: the art and science of material selection in product design. Butterworth-Heinemann. p. 223. ISBN 978-0-7506-5554-5. https://archive.org/details/materialsdesigna0000ashb. Retrieved 12 May 2011.
- Frederick James Camm (1949). Newnes Engineer's Reference Book. George Newnes. p. 594. https://books.google.com/books?id=iXxGAAAAMAAJ.
- Copper Development Association. "Pub 117 The Brasses – Properties & Applications". http://www.copperinfo.co.uk/alloys/brass/downloads/117/117-section-6-types-of-brass.pdf.
- "Is Brass Magnetic? What Is Magnetic Brass?" (in en-US). 1 January 2020. https://www.scrapmetaljunkie.com/2105/is-brass-magnetic-what-is-magnetic-brass.
- Metals in America's Historic Buildings: Uses and Preservation Treatments. U.S. Department of the Interior, Heritage Conservation and Recreation Service, Technical Preservation Services. 1980. p. 119. https://books.google.com/books?id=g7fCMfvnCKAC&pg=PA119.
- Stagnation Time, Composition, pH, and Orthophosphate Effects on Metal Leaching from Brass. Washington DC: United States Environmental Protection Agency. September 1996. p. 7. EPA/600/R-96/103. https://cfpub.epa.gov/si/si_public_record_report.cfm?Lab=NRMRL&dirEntryId=126033.
- News & Alerts – California Dept. of Justice – Office of the Attorney General. 12 October 1999. ,
- News & Alerts – California Dept. of Justice – Office of the Attorney General. 27 April 2001.
- San Francisco Superior Court, People v. Ilco Unican Corp., et al. (No. 307102) and Mateel Environmental Justice Foundation v. Ilco Unican Corp., et al. (No. 305765)
- AB 1953 Assembly Bill – Bill Analysis . Info.sen.ca.gov. Retrieved on 9 December 2011.
- Requirements for Low Lead Plumbing Products in California , Fact Sheet, Department of Toxic Substances Control, State of California, February 2009
- "Corrosion-Resistant (DZR or CR) Brass For Harsh Environments". 2016-05-24. https://www.rubinc.com/corrosion-resistant-dzr-or-cr-brass-for-harsh-environments/.
- "Brass". https://oceanfootprint.co.uk/product-category/metal-grades/brass/.
- "Specifications". https://www.metalalloyscorporation.com/pdf/c352-dezincification-resistant-brass.pdf.
- "Red Brass/Gunmetals". https://www.copper.org/applications/marine/other-copper-alloys/brasses/red-brass-gunmetals.html.
- "Gunmetal | metallurgy". https://www.britannica.com/technology/gunmetal.
- "What is Naval Brass?". 2013-05-17. https://www.nationalbronze.com/News/what-is-naval-brass/.
- Bell, Terence. "Here's Why Alloys Can Change the Properties of Brass". https://www.thoughtco.com/composition-of-common-brass-alloys-2340109.
- "Copper in the Arts Magazine - August 2007: The Art of Brass Instruments". https://www.copper.org/consumers/arts/2007/august/Art_History_Brass_Musical_Instruments.html.
- "EPA registers copper-containing alloy products", May 2008
- Michel, James H.; Moran, Wilton; Michels, Harold; Estelle, Adam A. (June 20, 2011). "Antimicrobial copper displaces stainless steel, germs for medical applications: Alloys have natural germ-killing properties". Tube and Pipe Journal. http://www.thefabricator.com/article/metalsmaterials/antimicrobial-copper-displaces-stainless-steel-germs-for--medical-applications.
- Noyce, J. O.; Michels, H.; Keevil, C. W. (2006). "Potential use of copper surfaces to reduce survival of epidemic methicillin-resistant Staphylococcus aureus in the healthcare environment". Journal of Hospital Infection 63 (3): 289–297. doi:10.1016/j.jhin.2005.12.008. PMID 16650507. http://www.coppercanada.ca/antimicrobial/antimicrobial_PDFs/Noyce%20-%20Potential%20use%20of%20cu%20surfaces%20to%20reduce%20survival%20of%20epidemic%20meticillin%20resistant%20staphylococcus%20aureus.pdf.
- Schmidt, MG (2011). "Copper surfaces in the ICU reduced the relative risk of acquiring an infection while hospitalized". BMC Proceedings 5 (Suppl 6): O53. doi:10.1186/1753-6561-5-S6-O53.
- "TouchSurfaces Clinical Trials: Home". coppertouchsurfaces.org. http://www.coppertouchsurfaces.org.
- "355 Copper Alloys Now Approved by EPA as Antimicrobial". Appliance Magazine. June 28, 2011. http://www.appliancemagazine.com/news.php?article=1498614&zone=0&first=1.
- Kuhn, Phyllis J. (1983). "Doorknobs: A Source of Nosocomial Infection?" Diagnostic Medicine
- Espίrito Santo, Christopher; Taudte, Nadine; Nies, Dietrich H.; and Grass, Gregor (2007). "Contribution of copper ion resistance to survival of Escherichia coli on metallic copper surfaces". Applied and Environmental Microbiology 74 (4): 977–86. doi:10.1128/AEM.01938-07. PMID 18156321.
- Santo, C. E.; Lam, E. W.; Elowsky, C. G.; Quaranta, D.; Domaille, D. W.; Chang, C. J.; Grass, G. (2010). "Bacterial Killing by Dry Metallic Copper Surfaces". Applied and Environmental Microbiology 77 (3): 794–802. doi:10.1128/AEM.01599-10. PMID 21148701.
- Scott, David A. (2002) (in en). Copper and Bronze in Art: Corrosion, Colorants, Conservation. Getty Publications. ISBN 9780892366385. https://books.google.com/books?id=yQKuSOzkLvcC&q=brass+susceptible+to+stress+corrosion+cracking&pg=PA31.
- Bradley, A. J.; Thewlis, J. (1 October 1926). "The Structure of γ-Brass". Proceedings of the Royal Society 112 (762): 678–692. doi:10.1098/rspa.1926.0134. Bibcode: 1926RSPSA.112..678B.
- Simons, E. N. (1970). A Dictionary of Alloys, Cornell University
- Joseph R. Davis (1 January 2001). Copper and Copper Alloys. ASM International. p. 7. ISBN 978-0-87170-726-0. https://books.google.com/books?id=sxkPJzmkhnUC&pg=PA249.
- "Brass Product Guide". https://alcobrametals.com/brass-product-guide/.
- manganese brass: Definition from. Answers.com. Retrieved on 2011-12-09.
- "464 Naval Brass (Tobin Bronze)". Kormax Engineering Supplies. https://kormax.co.nz/products/464-naval-brass/.
- National Pollutant Inventory – Copper and compounds fact sheet . Npi.gov.au. Retrieved on 9 December 2011.
- Ammen, C. W. (2000). Metalcasting. McGraw–Hill Professional. p. 133. ISBN 978-0-07-134246-9. https://archive.org/details/metalcasting00cwam.
- Jeff Pope (23 February 2009). "Plumbing problems may continue to grow". Las Vegas Sun. http://www.lasvegassun.com/news/2009/feb/23/plumbing-problems-may-continue-grow/. "... Red brass typically has 5 percent to 10 percent zinc ..."
- "C23000 Copper Alloys (Red Brass, C230) Material Property Data Sheet". http://www.suppliersonline.com/propertypages/C23000.asp.
- Surveying Yachts and Small Craft. Adlard Coles. 2011. p. 125. ISBN 9781408114032. https://books.google.com/books?id=ULky89_6e0QC&pg=PA125. "Beware of through hull fittings and tailpipes, or any other component in the assembly, made of TONVAL. This is basically brass and totally unsuitable for use below the waterline due to its tendency to dezincify and disintegrate"
- Print Layout 1 . (PDF) . Retrieved on 9 December 2011.
- Thornton, C. P. (2007) "Of brass and bronze in prehistoric southwest Asia" in La Niece, S. Hook, D. and Craddock, P.T. (eds.) Metals and mines: Studies in archaeometallurgy London: Archetype Publications. ISBN:1-904982-19-0
- de Ruette, M. (1995) "From Contrefei and Speauter to Zinc: The development of the understanding of the nature of zinc and brass in Post Medieval Europe" in Hook, D. R. and Gaimster, D. R. M (eds). Trade and Discovery: The Scientific Study of Artefacts from Post Medieval Europe and Beyond. London: British Museum Occasional Papers 109
- Cruden's Complete Concordance p. 55
- Craddock, P. T. and Eckstein, K (2003) "Production of Brass in Antiquity by Direct Reduction" in Craddock, P. T. and Lang, J. (eds.) Mining and Metal Production Through the Ages. London: British Museum, pp. 226–27
- Rehren and Martinon Torres 2008, pp. 170–175
- Chen, Hailian (2018-12-03) (in en). Zinc for Coin and Brass: Bureaucrats, Merchants, Artisans, and Mining Laborers in Qing China, ca. 1680s–1830s. BRILL. ISBN 978-90-04-38304-3. https://books.google.com/books?id=z2d9DwAAQBAJ&q=%22yellow+copper%22+brass&pg=PA93.
- Humphreys, Henry Noel (1897) (in en). The Coin Collector's Manual: Comprising an Historical and Critical Account of the Origin and Progress of Coinage, from the Earliest Period to the Fall of the Roman Empire; with Some Account of the Coinages of Modern Europe, More Especially of Great Brit. Bell. https://books.google.com/books?id=OhoLAAAAIAAJ&q=%22yellow+copper%22+brass&pg=PA374.
- Thornton 2007, pp. 189–201
- Zhou Weirong (2001). "The Emergence and Development of Brass Smelting Techniques in China". Bulletin of the Metals Museum of the Japan Institute of Metals 34: 87–98. http://sciencelinks.jp/j-east/article/200112/000020011201A0425152.php.
- Craddock and Eckstein 2003 p. 217
- Thornton, C. P. and Ehlers, C. B. (2003) "Early Brass in the ancient Near East", in IAMS Newsletter 23 pp. 27–36
- Bayley 1990, p. 8
- "orichalc – definition of orichalc in English from the Oxford dictionary". oxforddictionaries.com. http://www.oxforddictionaries.com/definition/english/orichalc?q=orichalcum.
- Rehren and Martinon Torres 2008, p. 169
- Craddock, P. T. (1978). "The Composition of Copper Alloys used by the Greek, Etruscan and Roman Civilisations: 3 The Origins and Early Use of Brass". Journal of Archaeological Science 5: 1–16 (8). doi:10.1016/0305-4403(78)90015-8.
- Pliny the Elder Historia Naturalis XXXIV 2
- "Atlantis' Legendary Metal Found in Shipwreck". DNews. 2017-05-10. http://news.discovery.com/history/archaeology/atlantis-legendary-metal-found-in-shipwreck-150106.htm.
- Jessica E. Saraceni. "Unusual Metal Recovered from Ancient Greek Shipwreck – Archaeology Magazine". archaeology.org. http://www.archaeology.org/news/2874-150107-sicily-orichalcum-metal.
- Craddock, P. T.; Cowell, M.; Stead, I. (2004). "Britain's first brass". Antiquaries Journal 84: 339–46. doi:10.1017/S000358150004587X.
- Montero-Ruis, I. and Perea, A. (2007). "Brasses in the early metallurgy of the Iberian Peninsula". In La Niece, S., Hook, D., and Craddock, P. T. (eds.). Metals and mines: Studies in archaeometallurgy. London: Archetype, pp. 136–40
- Craddock and Eckstein 2003, pp. 216–7
- Craddock and Eckstein 2003, p. 217
- Bayley 1990, p. 9
- Craddock and Eckstein 2003, pp. 222–224. Bayley 1990, p. 10.
- Craddock, P. T., Burnett, A., and Preston, K. (1980). "Hellenistic copper-based coinage and the origins of brass". In Oddy, W. A. (ed.). Scientific Studies in Numismatics. British Museum Occasional Papers 18 pp. 53–64
- Caley, E. R. (1964). Orichalcum and Related Ancient Alloys. New York; American Numismatic Society
- Bayley 1990, p. 21
- Ponting, M. (2002). "Roman Military Copper Alloy Artefacts from Israel: Questions of Organisation and Ethnicity". Archaeometry 44 (4): 555–571. doi:10.1111/1475-4754.t01-1-00086. http://www.liv.ac.uk/sace/research/publications/Ponting_Archaeometry_MandG.pdf.
- Ponting, M. (2002). "Keeping up with the Roman Romanisation and Copper Alloys in First Revolt Palestine". IAMS 22: 3–6. http://www.liv.ac.uk/sace/research/publications/Ponting_IAMS_Galillee.pdf.
- Rehren, T (1999). "Small Size, Large Scale Roman Brass Production in Germania Inferior". Journal of Archaeological Science 26 (8): 1083–1087. doi:10.1006/jasc.1999.0402. http://www.ucl.ac.uk/archaeology/staff/profiles/rehren/Small%20Size%20Large%20Scale%201999.pdf. Retrieved 2011-05-12.
- Bachmann, H. (1976). "Crucibles from a Roman Settlement in Germany". Journal of the Historical Metallurgy Society 10 (1): 34–5.
- Rehren and Martinon Torres 2008, pp. 170–71
- Bayley 1990
- Craddock and Eckstein 2003, p. 224
- Dungworth, D (1996). "Caley's 'Zinc Decline' reconsidered". Numismatic Chronicle 156: 228–234.
- Craddock 1978, p. 14
- Craddock, P. T., La Niece, S. C., and Hook, D. (1990). "Brass in the Medieval Islamic World". In Craddock, P. T. (ed.), 2000 Years of Zinc and Brass. London: British Museum, p. 73
- Ponting, M. (1999). "East Meets West in Post-Classical Bet'shan'". Journal of Archaeological Science 26 (10): 1311–1321. doi:10.1006/jasc.1998.0373.
- Bayley 1990, p. 22
- Eremin, Katherine; Graham-Campbell, James; Wilthew, Paul (2002). "Analysis of Copper alloy artefacts from Pagan Norse Graves in Scotland". in Biro, K.T; Eremin, K.. Proceedings of the 31st International Symposium on Archaeometry. Oxford: Archaeopress. pp. 342–349.
- Gilmore, G. R. and Metcalf, D. M. (1980). "The alloy of the Northumbrian coinage in the mid-ninth century". In Metcalf, D. and Oddy, W. Metallurgy in Numismatics 1 pp. 83–98
- Day 1990, pp. 123–150
- Day 1990, pp. 124–133
- Noel Stratford, pp. 232, 245, in Zarnecki, George and others; English Romanesque Art, 1066–1200, 1984, Arts Council of Great Britain, ISBN:0728703866
- Craddock and Eckstein 2003, pp. 224–25
- Craddock et al. 1990, 78
- Craddock et al. 1990, pp. 73–76
- Craddock et al. 1990, p. 75
- Craddock et al. 1990, p. 76
- Rehren, T (1999) "The same... but different: A juxtaposition of Roman and Medieval brass making in Europe" in Young, S. M. M. (ed.) Metals in antiquity Oxford: Archaeopress pp. 252–257
- Craddock and Eckstein 2003, 226
- Rehren and Martinon Torres 2008, pp. 176–178
- Rehren and Martinon Torres 2008, pp. 173–175
- "The Ife Head" on the British Museum collection database. Accessed 26 May 2014
- Martinon Torres and Rehren 2002, pp. 95–111
- Martinon Torres and Rehren 2002, pp. 105–06
- Martinon Torres and Rehren 2002, p. 103
- Martinon Torres and Rehren 2002, p. 104
- Martinon Torres and Rehren 2002, p. 100
- Martinon Torres and Rehren 2008, 181–82, de Ruette 1995
- de Ruette 1995, 198
- Craddock and Eckstein 2003, 228
- de Ruette 1995, 198–9
- Craddock and Eckstein 2003, 226–27.
- Day 1990, p. 131
- Day 1991, pp. 135–144
- Day 1990, p. 138
- Craddock and Eckstein 2003, p. 227
- Day 1991, pp. 179–181
- Dungworth, D.; White, H. (2007). "Scientific examination of zinc-distillation remains from Warmley, Bristol". Historical Metallurgy 41: 77–83. http://cat.inist.fr/?aModele=afficheN&cpsidt=19926763.
- Day 1991, p. 183
- Day, J. (1988). "The Bristol Brass Industry: Furnaces and their associated remains". Journal of Historical Metallurgy 22 (1): 24.
- Day 1991, pp. 186–189
- Day 1991, pp. 192–93, Craddock and Eckstein 2003, p. 228
- Bayley, J. (1990). "The Production of Brass in Antiquity with Particular Reference to Roman Britain". In Craddock, P. T. (ed.). 2000 Years of Zinc and Brass. London: British Museum.
- Craddock, P. T. and Eckstein, K (2003). "Production of Brass in Antiquity by Direct Reduction". In Craddock, P. T. and Lang, J. (eds.). Mining and Metal Production Through the Ages. London: British Museum.
- Day, J. (1990). "Brass and Zinc in Europe from the Middle Ages until the 19th century". In Craddock, P. T. (ed.). 2000 Years of Zinc and Brass. London: British Museum.
- Day, J. (1991). "Copper, Zinc and Brass Production". In Day, J. and Tylecote, R. F. (eds.). The Industrial Revolution in Metals. London: The Institute of Metals.
- Martinon Torres, M.; Rehren, T. (2002). "Agricola and Zwickau: theory and practice of Renaissance brass production in SE Germany". Historical Metallurgy 36 (2): 95–111.
- Rehren, T. and Martinon Torres, M. (2008) "Naturam ars imitate: European brassmaking between craft and science". In Martinon-Torres, M. and Rehren, T. (eds.). Archaeology, History and Science: Integrating Approaches to Ancient Material. Left Coast Press.
Original source: https://en.wikipedia.org/wiki/Brass. Read more