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Ironsand

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Iron sand fromPhoenix,Arizona,attracted to a magnet

Ironsand,also known asiron-sandoriron sand,is a type ofsandwith heavy concentrations ofiron.It is typically dark grey or blackish in color.

It is composed mainly ofmagnetite,Fe3O4,and also contains small amounts of titanium, silica, manganese, calcium and vanadium.[1]

Ironsand has a tendency to heat up in directsunlight,causingtemperatureshigh enough to cause minor burns. As such it forms a hazard inNew Zealandat popular west-coast surf beaches such asPiha.[2]

Occurrence

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Ironsand is found worldwide. Although the iron mineral composition of the ironsand is mostly magnetite, the sand is usually mixed with other types of sand that wash downriver or ashore from mountainous or underwater deposits.[3]The exact composition of the sand mixture may vary drastically even in the same geographic region. In some areas the sand may contain mostlyquartz,while in others the sand may be made primarily fromvolcanic rocksuch asbasalt,depending on the types of minerals along the water's path. The ironsand is typically picked up along the way from beds, veins, or inclusions of magnetite, which may originate a great distance from the sand deposits, and washed downstream or along the currents with the rest of the sand.[4]Being heavier than the other sands, it is often deposited in areas where the water experiences a sudden change in direction or speed, such as the widening of a river or where the waves ebb and flow against the shoreline.[5]

The ironsand is mixed with the other sands as small grains of black or dark-blue magnetite. Sand used for mining typically had anywhere from 19% magnetite to as low as 2%. The ironsand typically had to be separated from the sand mixture. Because the magnetite is usually heavier than quartz, feldspar, or other minerals, separation was usually done by washing it insluice boxes(a method similar togold panningbut on a larger scale). Sluice separation typically yielded concentrations of magnetite ranging from 30 to 50%, depending on the type of sand and the method used. In the early 20th century a process of magnetic separation was developed that could produce concentrations as high as 70%.[6]Once concentrated, the magnetite grains could then besmeltedinto various forms of iron. However, the loose, granular nature of the ore was difficult to keep contained in common bloomeries or blast furnaces, having a tendency towardgranular flow(mimicking a liquid at larger scales) and was easily blown away by the bellow blasts, so was impossible to process using common methods of iron or steel production. Thus, innovative methods of smelting the ore were developed. The magnetite grains, however, often contain othermetalimpurities, such aschromium,arsenic,ortitanium.[7]Due to the nature of the sand the mining operations were rarely stationary, but frequently moved from place to place.[8]

Asia

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Historically, ironsand was predominantly used inEast Asiancultures; most notably in China and Japan.

China

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Ironsand had moderate, localized uses in China during the lateIndustrial Revolution,but was a rather unimportant commodity throughout the long history of the Chinese iron-industry. Unlike the rest ofEurasiaandAfrica,there is very little archeological evidence to suggest that bloomery smelting was used in ancientChina.[9]The Chinese countryside was rich in deposits that contained bothcoal,a fuel that burns at a high temperature, and an iron ore containing a high content ofphosphorus.Around 1200 BC the Chinese developed a method of smelting the rocky ore into pig iron, which was then remelted and poured into molds (cast) to form cast iron. Although the metal was very brittle, this method was able to produce iron in much greater volumes than bloomery smelting, and with vastly higheryieldsof metal per ore. By the 1st century BC the Chinese iron-industry was by far the largest and most advanced in the world. By the 1st century AD they had developedpuddlingfor the production ofmild steel,crucible steelfor the manufacture of swords and weapons, and a chemical process of rapidlydecarburizingliquid pig-iron to make wrought iron, using theoxidationproperties ofsaltpeter(called theHeaton process,it was independently discovered byJohn Heatonin the 1860s).[10]China remained the world's largest producer of iron until the 11th century, manufacturing large quantities of relatively affordable steel and iron.[11][12]

Donald B Wagner, an expert in ancient Chinese metallurgy, notes that attempts to trace the history of ironsand in China end with inconclusive results. One source may indicate its use as early as the Tang Dynasty (~700-900 AD) while others seem to contradict this interpretation.[13]Due to wars, invasions, famines, distrust of the government, overpopulation, a risingopiumepidemic, and clashes between varioustongsof miners, very little information exists about the industry between the 11th century and the 19th century, when a European miner named Felix Tegengren arrived to find the Chinese industry in shambles. Tegengren notes that ironsand was sluice mined in Henan and Fu gian by local farmers and smelted over charcoal fires to make tools, but it involved a lot of work, which made it very expensive. It was only smelted where there was enough wood for the fires and cheaper steel was not readily available. Therefore, the material was considered to be economically unimportant in China.[14][15]However, because the mining was safe, outdoor work, it was practiced by local farmers to supplement their income wherever it was available; in the 19th century 1,000 lb (450 kg) of sluiced sand typically sold for the equivalent of 50 to 60 US dollars (by 2016 exchange rates ~ 900--1000 dollars or 700--800 euros).[16]

However, in the modern age ironsand isplacer minedalong China's southeast coast and used for smelting steel.[17][18]The typical composition of this ironsand is 48.88% metallic iron, 25.84% silica, 0.232% phosphorus, and 0.052% sulfur.[19]

Indonesia

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In Indonesia, iron sand is prevalent on the south coast ofJava island.

Japan

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Large scale mining was not practiced inJapanuntil the 7th or 8th centuries. Prior to this, metals were commonly imported into Japan from China and Korea.[20]Deposits ofiron oreare thought to have been scarce in Japan, so, around the 8th century, iron-making technology developed with the use of ironsand (satetsu) as the raw ingredient. Because of the loose nature of the sand it was difficult to smelt in a normalbloomery,or to use in ablast furnaceto makepig iron,so the Japanese developed an open-topped bloomery called atatara.The tatara was built with a low, tub-like shape, resembling a horizontal blast-furnace, into which ironsand could be poured and contained, and smelted in stages. Unlike with other methods, the charcoal was piled on top of the sand and smelted from above, keeping it from being blown about by the blasts from thebellows.Instead of brick or stone, the tatara was made of clay so that it could simply be broken apart to extract the metal bloom. This method allowed smelting of much higher volumes of ore than other types of bloomery smelting.

The ironsand in Japan comes in two forms.Masaironsand is found mixed withquartzsand that washes down fromgranitemountains. The magnetite in the sand contains few impurities or other metal oxides.Masaironsand was used for manufacturingwrought ironandsteel,used in everything from tools to cookware. Ironsand was used extensively in Japan for iron production, especially for traditionalJapanese swords.[21]

Akomeironsand is found mixed with sand made from anigneous rockcalleddiorite.The magnetite in the sand contains often greater than 5%titanium dioxide,which lowers the smelting temperature. Theakomeironsand is used in the tatara to make pig iron, which is then used to make items out ofcast iron(nabegane). In the manufacture of steel, theakomewas added to the tatara during the initial stage of smelting, acting as a binder and catalyst for steel production, upon which themasaironsand was poured during further stages.[22][23]When smelted for pig iron, 1,000 lb (450 kg) or 120kanme) typically yielded about 200 lb (91 kg) of pig iron, 20 lb (9.1 kg) of steel, and 70 lb (32 kg) of slag. When smelted for steel, 1,000 lb (450 kg) of sand yielded about 100 lb (45 kg) of steel, 100 lb (45 kg) of slag, and 90 lb (41 kg) of pig iron. Slag and pig iron that were not suitable for use were then melted together to form wrought iron, of which 1,000 lb (450 kg) mixed produced about 500 lb (230 kg) of iron.[24]

Europe

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Ironsand is found many places in Europe, although it was rarely used for smelting. It is often found in association with volcanic or basaltic sands. For example, it is found inTenerife,Spain,where the magnetite grains contain a very high amount of titanium and other impurities. The typical composition is 79.2% iron oxide, 14.6% titanium dioxide, 1.6%manganese oxide,0.8% silica andaluminum oxide,and trace amounts ofchromium.It can also be found in theRiver Dee,inAberdeenshire, Scotland,containing 85.3% iron oxide, 9.5% titanium dioxide, 1.0%arsenic,and 1.5% silica and aluminum oxide.[25]

New Zealand

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Ironsand occurs extensively on the west coast ofNew Zealand'sNorth Island.[26]The sand makes up a large portion of the black-sand beaches on the North Island, as well as the surrounding sea floor. The magnetite in the sand contains fairly large quantities of titanium, and is sometimes referred to as titanomagnetite. It was produced from volcanic eruptions that occurred in thePleistocene epoch,and is formed due to the oceanic erosion of the volcanic rock which is washed ashore by the waves to form the dunes of the black beaches. The magnetite is mixed with sand made fromandesiteandrhyolite.[27]The sand mixture typically contains 5 to 40% magnetite.[28]

New Zealand had limited deposits of iron ore, but the deposits of ironsand were massive. It had been used by some early settlers to manufacture steel and pig iron, but the material could not be smelted in common bloomeries or blast furnaces.[29]A few smelting companies formed in the late 19th and early 20th centuries, but were unable to process the ore with any economic success due to the sandy nature and high titanium content, which tended to form hard, brittle carbides in the steel. In 1939, a commission was formed to study the properties of the ore and devise a way of smelting it on an industrial scale. The commission determined that, bysinteringthe sand into bigger chunks or pellets, the problems of smelting the sand in a blast furnace could be eliminated.[30]However, at that timeWorld War IIbegan, and thus further development was suspended and did not resume until the late 1960s, producing the first output of steel in 1969.[31]

Ironsand is placer mined from Waikato North Head. 1.2 million tonnes is used byNew Zealand Steelto createsteel,in a unique manufacturing process. Mining atTaharoaproduces up to 4 million tonnes for export. A previous mine existed atWaipipiin South Taranaki. A proposal byIron Ore NZ Ltd.for further ironsandminingoff the coast ofTaranakifaced resistance from someMāoriand others in 2005 in the wake of theNew Zealand foreshore and seabed controversy.[32]A large quantity of it is shipped to China and Japan, but by 2011 New Zealand's sole manufacturing plant was producing 650,000 metric tons of steel and iron per year.[33]New Zealand is the only country to use ironsand for industrial smelting.[34]The typical composition of the magnetite is 82%iron oxide,8%titanium dioxideand 8%silica;0.015%sulfur,and 0.015%phosphorus.In 100% concentrations of magnetite this had a maximum potential to yield ~ 58% metallic iron, although the titanium is unrecoverable by modern techniques.[35]

United States

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Ironsand is found extensively around the US, especially in the area ofNew York,Southern California,New England,and theGreat Lakes,where it is often mixed with a feldspar sand and sometimes bright grains ofgarnet.The magnetite from these areas often contains high amounts of chromium and titanium.[36]In the 19th century ironsand was sometimes used as blotter sand for concrete and masonry work, or more rarely as raw material for steel production; one blacksmith inConnecticutused it for makingbar stock.[37]

History

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According to theOEDonline entry forsand-iron,Jedidiah Morse(1761–1826), writing inThe American universal geography(new edition, 1796 (2 vols)), stated thatJared Eliot(1685-1763) invented sand-iron, or the making ofironfromblack sand,in 1761.[38] However, Japanese craftsmen have been using sand-iron, known as "tamahagane",insword-makingfor at least 1200 years. The crafting of sand-iron in "tatara"smelters, made of brick and clay, is still practiced by Japanese craftsmen today.

See also

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References

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  1. ^Templeton, Fleur (24 September 2011)."Chemical composition of ironsands - Iron and steel".Te Ara Encyclopedia of New Zealand.Archivedfrom the original on 19 January 2012.Retrieved4 January2013.
  2. ^"Summer Beach Vacation Piha Beach New Zealand - Photo & Travel Idea New Zealand".New Zealand Pictures.2013. Archived fromthe originalon 5 May 2013.Retrieved4 January2013.The beach is made up of black iron sand which can become overly hot during the summer and walking in the water or with shoes on will protect your feet from burning.
  3. ^Random Seas and Design of Maritime Structures: Third Editionby Yoshimi Goda -- World Scientific Publishing 2010 Page 604
  4. ^Mineralogy of New-Yorkby Lewis Caleb Beck -- Thurloe Weed Printer 1842 Page 22
  5. ^Science and Civilisation in China: Volume 5by Joseph Needham -- Page 343--347
  6. ^Dabieshan: Traditional Chinese Iron-production Techniques Practised in Southern Henan in the Twentieth Centuryby Donald B Wagner -- Curzon Press 1985 Page 31--32
  7. ^Graphics and Text in the Production of Technical Knowledge in Chinaby Francesca Bray, Vera Dorofeeva-Lichtmann, Georges Métailié -- Koninklijke Brill Nv 2007 Page 616
  8. ^Dabieshan: Traditional Chinese Iron-production Techniques Practised in Southern Henan in the Twentieth Centuryby Donald B Wagner -- Curzon Press 1985 Page 31--32
  9. ^Still the Iron Age: Iron and Steel in the Modern Worldby Vaclav Smil -- Elsevier 2016 Page 6
  10. ^Scientific American -- Conversion of cast iron into wrought iron
  11. ^The Traditional Chinese Iron Industry and its Modern Fate by Donald B Wagner
  12. ^Science and Civilisation in China: Volume 5by Joseph Needham -- Page 345
  13. ^Dabieshan: Traditional Chinese Iron-production Techniques Practised in Southern Henan in the Twentieth Centuryby Donald B Wagner -- Curzon Press 1985 Page 31--32
  14. ^Graphics and Text in the Production of Technical Knowledge in Chinaby Francesca Bray, Vera Dorofeeva-Lichtmann, Georges Métailié -- Koninklijke Brill Nv 2007 Page 616
  15. ^The Chinese in America: A History from Gold Mountain to the New Millenniumby Susie Lan Cassel -- Altamira Press 2002 Page 43--46
  16. ^Science and Civilisation in China: Volume 5by Joseph Needham -- Page 343--347
  17. ^The Chinese in America: A History from Gold Mountain to the New Millenniumby Susie Lan Cassel -- Altamira Press 2002 Page 43--46
  18. ^Science and Civilisation in China: Volume 5by Joseph Needham -- Page 343--347
  19. ^Dabieshan: Traditional Chinese Iron-production Techniques Practised in Southern Henan in the Twentieth Centuryby Donald B Wagner -- Curzon Press 1985 Page 31--32
  20. ^The Mining Industry of Japan During the Last Twenty Five Years, 1867-1892by Tsunashirō Wada -- Director of Mining Bureau, Department of Agriculture and Commerce Japan 1893 Page 1
  21. ^"The Tatara Iron Manufacturing Method".Hitachi Metals.Archivedfrom the original on 31 March 2015.Retrieved20 January2015.
  22. ^"Hitachi Metals>Tale of tatara>The Tatara Iron Manufacturing Method".Archived fromthe originalon 31 March 2015.Retrieved20 January2015.
  23. ^Still the Iron Age: Iron and Steel in the Modern Worldby Vaclav Smil -- Elsevier 2016 Page 6
  24. ^The Mining Industry of Japan During the Last Twenty Five Years, 1867-1892by Tsunashirō Wada -- Director of Mining Bureau, Department of Agriculture and Commerce Japan 1893 Page 235
  25. ^The Cyclopædia: Or, Universal Dictionary of Arts, Sciences, and Literatureby Abraham Rees -- A. Strahan 1816 Page Mineralogy Iron-Iridium
  26. ^Templeton, Fleur (15 June 2010)."1. Iron – an abundant resource - Iron and steel".Te Ara Encyclopedia of New Zealand.Archivedfrom the original on 5 November 2012.Retrieved4 January2013.
  27. ^Minerals Yearbook - Area Reports: International Review: 2011, Volume 3by Interior Department, Geological Survey -- USGS 2013 Page 13-48
  28. ^New Zealand Journal of Science, Volume 22by Department of Science and Research 1979 Page 8
  29. ^The New Zealand mining handbookby New Zealand. Mines Dept, P. Galvin -- John Mackay 1906 Page 494--495
  30. ^DSIR: Making Science Work for New Zealand: Themes from the History of the Department of Scientific and Industrial Research, 1926--1992by Ross Galbreath -- Victoria University Press 1998 Page 182
  31. ^DSIR: Making Science Work for New Zealand: Themes from the History of the Department of Scientific and Industrial Research, 1926--1992by Ross Galbreath -- Victoria University Press 1998 Page 170--200
  32. ^"What is seabed mining?".Kiwis Against Seabed Mining.Archivedfrom the original on 2 February 2013.Retrieved19 January2013.
  33. ^Minerals Yearbook - Area Reports: International Review: 2011, Volume 3by Interior Department, Geological Survey -- USGS 2013 Page 13-48
  34. ^"First steel produced from local ironsand".
  35. ^The New Zealand mining handbookby New Zealand. Mines Dept, P. Galvin -- John Mackay 1906 Page 486--487
  36. ^Mineralogy of New-Yorkby Lewis Caleb Beck -- Thurloe Weed Printer 1842 Page 22
  37. ^Documents of the Assembly of the State of New York, Volume 4by New York (State). Legislature. Assembly -- E. Coswell Printing 1838 Page 136
  38. ^ "sand-iron".Oxford English Dictionary First Edition (Online version).1909.Retrieved16 December2013.
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