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History of metallurgy in China

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Bronze tiger inlaid with gold and silver, Han dynasty

Metallurgy in China has a long history, with the earliest metal objects in China dating back to around 3,000 BCE. The majority of early metal items found in China come from the North-Western Region (mainly Gansu and Qinghai, 青海). China was the earliest civilization to use the blast furnace and produce cast iron.[1]

Copper

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Archaeological evidence indicates that the earliest metal objects in China were made in the late fourth millennium BCE. Copper was generally the earliest metal to be used by humanity, and was used in China since at least 3000 BCE.[2][3]

Historical influences on Chinese metallurgy. After a small early copper industry in the Neolithic, China was influenced by the metallurgy of the steppes (Andronovo culture), the Seima-Turbino phenomenon and the Karasuk culture down to the Shang dynasty period.[4]

Early metal-using communities have been found at the Qijia and Siba sites in Gansu. The metal knives and axes recovered in Qijia apparently point to some interactions with Siberian and Central Asian cultures, in particular with the Seima-Turbino complex,[5] or the Afanasievo culture.[6] Archeological evidence points to plausible early contact between the Qijia culture and Central Asia.[5] Similar sites have been found in Xinjiang in the west and Shandong, Liaoning and Inner Mongolia in the east and north. The Central Plain sites associated with the Erlitou culture also contain early metalworks.[7]

Copper manufacturing, more complex than jade working, gradually appeared in the Yangshao period (5000–3000 BCE). Jiangzhai is the only place where copper artifacts were found in the Banpo culture. Archaeologists have found remains of copper metallurgy in various cultures from the late fourth to the early third millennia BCE. These include the copper-smelting remains and copper artifacts of the Hongshan culture (4700–2900) and copper slag at the Yuanwozhen site. This indicates that inhabitants of the Yellow River valley had already learned how to make copper artifacts by the later Yangshao period.[8]

The Qijia culture (c. 2500–1900) of Qinghai, Gansu, and western Shaanxi produced copper and bronze utilitarian items and gold, copper, and bronze ornaments. The earliest metalworks in this region are found at a Majiayao site at Linjia, Dongxiang, Gansu.[7] "Their dates range from 2900 to 1600 BCE. These metal objects represent the Majiayao 馬家窯 type of the Majiayao culture (c. 3100–2700 BCE), Zongri 宗日 Culture (c. 3600–2050 BCE), Machang 馬廠 Type (c. 2300–2000 BCE), Qijia 齊家 Culture (c. 2050–1915 BCE), and Siba 四壩 Culture (c. 2000–1600 BCE)."[9]

At Dengjiawan, in the Shijiahe site complex in Hubei, some pieces of copper were discovered; they are the earliest copper objects discovered in southern China.[10] The Linjia site (林家遺址, Línjiā yízhǐ) has the earliest evidence for bronze in China, dating to c. 3000 BCE.[11]

Bronze

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Bronze knife found in Dongxiang, Gansu (dated 2900–2740 BC), Majiayao culture
Bronze spearhead with inscription, Zhou dynasty

Bronze technology was imported to China from the steppes.[12] The oldest bronze object found in China was a knife found at a Majiayao culture site in Dongxiang, Gansu, and dated to 2900–2740 BC.[13] Further copper and bronze objects have been found at Machang-period sites in Gansu.[14] Metallurgy spread to the middle and lower Yellow River region in the late 3rd millennium BC.[15] Contacts between the Afanasievo culture and the Majiayao culture and the Qijia culture have been considered for the transmission of bronze technology.[16] From around 2000 BCE, cast bronze objects such as the socketed spear with single side hook were imported and adapted from the Seima-Turbino culture.[17]

The Erlitou culture (c. 1900 – 1500 BCE), Shang dynasty (c. 1600 – 1046 BCE) and Sanxingdui culture (c. 1250 – 1046 BCE) of early China used bronze vessels for rituals (see Chinese ritual bronzes) as well as farming implements and weapons.[18] By 1500 BCE, excellent bronzes were being made in China in large quantities, partly as a display of status, and as many as 200 large pieces were buried with their owner for use in the afterlife, as in the Tomb of Fu Hao, a Shang queen.

In the tomb of the first Qin Emperor and multiple Warring States period tombs, extremely sharp swords and other weapons were found, coated with chromium oxide, which made the weapons rust resistant.[19][20][21] The layer of chromium oxide used on these swords was 10 to 15 micrometers and left them in pristine condition to this day. Chromium was first scientifically attested in the 18th century.[22]

The beginning of new breakthroughs in metallurgy occurred towards the Yangzi River's south in China's southeastern region in the Warring States period such as gilt-bronze swords.[23]

Section-mold casting

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There are two types of bronze smelting techniques in early China, namely the section mold process and the lost-wax process. The earliest bronze ware found in China is the bronze knife (F20: 18) unearthed at the Majiayao in Linjia, Dongxiang, Gansu, and dated to about 3000 BC.[24] This bronze knife uses the section mold process, which is spliced by two molds.

The section mold process is a commonly used bronze casting method in the Shang dynasty, that is, the mud is selected, and after selecting, filtration, showering, deposition and other procedures, the mud is cooled to a moderate hardness as a backup, and then the mud is made according to the shape of the vessel to be made. There are two types of molds, which is inner mold and outer mold. The inner mold is only the shape of the bronze ware, without decoration; the outer model should consider the division of the bronze ware after casting in the future, that is, the block during the production of the clay model, and also engrave the inscriptions and inscriptions of the bronze ware decoration on the clay model. After the clay mold are done, put it in a cool place to dry in the shade, and then put it into the furnace for roasting. After the mold are heated, they become pottery molds unearthed during modern archaeological discoveries. After the pottery mold is fired, do not rush out of the furnace. After the copper furnace has liquefied the required copper, the pottery mold that still has residual temperature is taken out and poured. In this way, the temperature difference between the copper liquid and the pottery mold is not large, and the pottery mold is not easy to burst. The quality of the finished product is relatively high. After the copper liquid is poured, remove the pottery molds and molds according to the blocks they were made. If they can't be removed, they can be broken with a hammer. The bronze will come out, and after grinding, it is the finished product.[25]

Lost-wax casting

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According to some scholars, lost-wax casting was used in China already during the Spring and Autumn period (770 – 476 BCE), although this is often disputed.[26]

The lost-wax method is used in most parts of the world. As the name suggests, the lost-wax method is to use wax as a mold, and heat it to melt the wax mold and lose it, thereby casting bronze ware, making the model (the outer layer of the wax model is coated with mud), lost-wax (heating to make the wax flow out), pouring copper liquid to fill the cavity left by the wax model, etc. The development and spread of the lost-wax method in the West has never stopped, but the main bronze casting method in the Bronze Age in China is the section mold process. When the lost-wax method was introduced into China is also a topic of academic discussion. But there is no doubt that the lost-wax method already existed in China during the Spring and Autumn period. In 1978, the Bronze Zun-Pan unearthed from the tomb of Marquis Yi of Zeng in Leigudun, Suixian County, Hubei Province, used a mixed process of section mold method and lost-wax method.[27]

Iron

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A Chinese blast furnace, pouring out iron
Iron sickle and plow, Han dynasty

Introduction

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The early Iron Age in China began before 1000 BCE, with the introduction of ironware, such as knives, swords, and arrowheads, from the west into Xinjiang, before it further diffused to Qinghai and Gansu.[28] In 2008, two iron fragments were excavated at the Mogou site, in Gansu. They have been dated to the 14th century BCE, belonging to the period of Siwa culture. One of the fragments was made of bloomery iron rather than meteoritic iron.[29]

Cast iron

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Cast iron farm tools and weapons were widespread in China by the 5th century BC, employing workforces of over 200 men in iron smelters from the 3rd century onward. The earliest known blast furnaces are attributed to the Han dynasty in the 1st century AD.[30][31] These early furnaces had clay walls and used phosphorus-containing minerals as a flux.[32] Chinese blast furnaces ranged from around two to ten meters in height, depending on the region. The largest ones were found in modern Sichuan and Guangdong, while the 'dwarf" blast furnaces were found in Dabieshan. In construction, they are both around the same level of technological sophistication [33]

There is no evidence of the bloomery in China after the appearance of the blast furnace and cast iron. In China, blast furnaces produced cast iron, which was then either converted into finished implements in a cupola furnace, or turned into wrought iron in a fining hearth.[34] If iron ores are heated with carbon to 1420–1470 K, a molten liquid is formed, an alloy of about 96.5% iron and 3.5% carbon. This product is strong, can be cast into intricate shapes, but is too brittle to be worked, unless the product is decarburized to remove most of the carbon. The vast majority of Chinese iron manufacture, from the late Zhou dynasty onward, was of cast iron.[35] However forged swords began to be made in the Warring-States-period: "Earliest iron and steel Jian also appear, made by the earliest and most basic forging and folding techniques."[36] Iron would become, by around 300 BCE, the preferred metal for tools and weapons in China.[37]

The primary advantage of the early blast furnace was in large scale production and making iron implements more readily available to peasants.[38] Cast iron is more brittle than wrought iron or steel, which required additional fining and then cementation or co-fusion to produce, but for menial activities such as farming it sufficed. By using the blast furnace, it was possible to produce larger quantities of tools such as ploughshares more efficiently than the bloomery. In areas where quality was important, such as warfare, wrought iron and steel were preferred. Nearly all Han period weapons are made of wrought iron or steel, with the exception of axe-heads, of which many are made of cast iron.[39]

The effectiveness of the Chinese human and horse powered blast furnaces was enhanced during this period by the engineer Du Shi (c. AD 31), who applied the power of waterwheels to piston-bellows in forging cast iron.[40] Early water-driven reciprocators for operating blast furnaces were built according to the structure of horse powered reciprocators that already existed. That is, the circular motion of the wheel, be it horse driven or water driven, was transferred by the combination of a belt drive, a crank-and-connecting-rod, other connecting rods, and various shafts, into the reciprocal motion necessary to operate a push bellow.[41][42]

Donald Wagner suggests that early blast furnace and cast iron production evolved from furnaces used to melt bronze. Certainly, though, iron was essential to military success by the time the State of Qin had unified China (221 BC). Usage of the blast and cupola furnace remained widespread during the Song and Tang dynasties.[43] By the 11th century, the Song dynasty Chinese iron industry made a switch of resources from charcoal to coke in casting iron and steel, sparing thousands of acres of woodland from felling. This may have happened as early as the 4th century AD.[44][45]

Blast furnaces were also later used to produce gunpowder weapons such as cast iron bomb shells and cast iron cannons during the Song dynasty.[46]

Middle Ages

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Shen Kuo's written work of 1088 contains, among other early descriptions of inventions, a method of repeated forging of cast iron under a cold blast similar to the modern Bessemer process.[47][48][49][50][51][52][53]

Chinese metallurgy was widely practiced during the Middle Ages; during the 11th century, the growth of the iron industry caused vast deforestation due to the use of charcoal in the smelting process.[54][55] To remedy the problem of deforestation, the Song Chinese discovered how to produce coke from bituminous coal as a substitute for charcoal.[54][55] Although hydraulic-powered bellows for heating the blast furnace had been written about since Du Shi's (d. 38) invention of them in the 1st century CE, the first known illustration of a bellows in operation is found in a book written in 1313 by Wang Zhen (fl. 1290–1333).[56]

Gold and silver

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Geographical distribution of early gold and silver artefacts found in Northwest China and Central Asia (8th–3rd century BCE).[57]
Silver chopsticks, cup, and spoon, Song dynasty

Gold-crafting technology developed in Northwest China during the early Iron Age, following the arrival of new technological skills from the Central Asian steppes, even before the establishment of the Xiongnu (209 BCE-150 CE).[57] These technological and artistic exchanges attest to the magnitude of communication networks between China and the Mediterranean, even before the establishment of the Silk Road.[57] The sites of Dongtalede (Ch: 东塔勒德, 9th–7th century BCE) in Xinjiang, or Xigoupan (Ch:西沟畔, 4th–3rd century BCE) in the Ordos region of Inner Mongolia, are known for numerous artifacts reminiscent of the Scytho-Siberian art of Central Asia.[57]

During the Qing dynasty the gold and silver smiths of Ningbo were noted for the delicacy and tastefulness of their work.[58][59][60][61][62][63][64]

Cultural significance

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Chinese mythology generally reflects a time when metallurgy had long been practiced. According to the Romanian anthropologist, orientalist, and philosopher Mircea Eliade, the Iron Age produced a large number of rites, myths and symbols; the blacksmith was the main agent of diffusion of mythology, rites and metallurgical mysteries.[65] The secret knowledge of metallurgists and their powers made them founders of the human world and masters of the spirit world.[66] This metallurgical model was reinterpreted again by Taoist alchemists.

Some metalworkers illustrate the close relationship between Chinese mystical and sovereign power and the mining and metallurgy industries. Although the name Huangdi is absent from Shang or Zhou inscriptions, it appears in the Spring and Autumn period's Guoyu and Zuo zhuan. According to Mitarai (1984), Huangdi may have lived in early antiquity and led a regional ethnic group who worshiped him as a deity;[full citation needed] "The Yellow Emperor fought Chiyou at Mount Kunwu whose summit was covered with a large quantity of red copper".[67]

"The seventy-two brothers of Chiyou had copper heads and iron fronts; they ate iron and stones [...] In the province of Ji where Chiyou is believed to have lived (Chiyou shen), when we dig the earth and we find skulls that seem to be made of copper and iron, they are identified as the bones of Chiyou."[68] Chiyou was the leader of the indigenous Sanmiao (or Jiuli) tribes who defeated Xuanyuan, the future Yellow Emperor. Chiyou, a rival of the Yellow Emperor, belonged to a clan of blacksmiths. The advancement of weaponry is sometimes attributed to the Yellow Emperor and Chiyou, and Chiyou reportedly discovered the process of casting. Kunwu is associated with a people, a royal blacksmith, a mountain which produces metals, and a sword.[69] Kui, a master of music and dance cited by Shun, was succeeded by Yu the Great. Yu the Great, reported founder of the Xia dynasty (China's first), spent many years working on flood control and is credited with casting the Nine Tripod Cauldrons. Helped by dragons descended from heaven, he died on Mount Xianglu in Zhejiang.[70] In these myths and legends, mines and forges are associated with leadership.[71]

See also

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References

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Citations

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  1. ^ In 200 BCE. Srinivasan, Sharda and Srinivasa Rangnathan. 2004. India's Legendary Wootz Steel. Bangalore: Tata Steel.[1] [2] [3]
  2. ^ Linduff 1997:306–418 (Linduff, K. M. 1997. An Archaeological Overview: Section 1. Reconstructing Frontier Cultures from Archaeological Evidence, in E. C. Bunker, et al., Ancient Bronzes of the Eastern Eurasian Steppes from the Arthur M. Sackler Collections, New York: The Arthur M. Sackler Foundation, 1997)
  3. ^ Mei 2000 (Mei, Jianjun 2000. Copper and Bronze Metallurgy in Late Prehistoric Xinjiang: Its cultural context and relationship with neighboring regions, BAR International Series 865, Oxford: Archaeopress.)
  4. ^ Grigoriev, Stanislav A. (2022). "Internal and External Impulses for the Development of Ancient Chinese Metallurgy". Geoarchaeology and Archaeological Mineralogy. Springer Proceedings in Earth and Environmental Sciences. Springer International Publishing: 8, Fig.2. doi:10.1007/978-3-030-86040-0_1. ISBN 978-3-030-86039-4. S2CID 245719183.
  5. ^ a b Cosmo, Nicola Di (2008). Northern Frontier in Pre-Imperial China (Cambridge History of Ancient China). Cambridge University Press. p. 901.
  6. ^ JIANJUN, MEI (2003). "Cultural Interaction between China and Central Asia during the Bronze Age" (PDF). Proceedings of the British Academy. 121: 1–39. the argument for possible Afanasievo-Xinjiang contact based on the finds at the Gumugou cemetery in the north-eastern rim of the Tarim basin would seem reasonable and needs to be kept open for the future archaeological finds. In other words, the possibility for the dispersal of early copperbased metallurgy from the Eurasian steppe into Xinjiang and further east to Gansu cannot be excluded at present and will have to be considered when further archaeological evidence becomes available.
  7. ^ a b Katheryn M. Linduff, Jianjun Mei (2008), Metallurgy in Ancient Eastern Asia: How is it Studied? Where is the Field Headed? (PDF) The British Museum
  8. ^ The Formation of Chinese Civilization: An Archaeological Perspective, Kwang-Chih Chang, Pingfang Xu, Liancheng Lu. Yale University Press (2005), p. 66
  9. ^ Bai Yunxiang (2003), A Discussion on Early Metals and the Origins of Bronze Casting in China. (PDF) Chinese Archaeology, Vol. 3(1)
  10. ^ Anne P. Underhill, ed., A Companion to Chinese Archaeology John Wiley & Sons, 2013 ISBN 1118325729 p524
  11. ^ Gideon Shelach, Prehistoric Societies on the Northern Frontiers of China: Archaeological Perspectives on Identity Formation and Economic Change During the First Millennium BCE. Routledge, 2016 ISBN 1134944810 p. 26
  12. ^ Rawson, Jessica (April 2017). "China and the steppe: reception and resistance". Antiquity. 91 (356): 375–388. doi:10.15184/aqy.2016.276. S2CID 165092308. The development of several key technologies in China —bronze and iron metallurgy and horse-drawn chariots— arose out of the relations of central China, of the Erlitou period (c. 1700–1500 BC), the Shang (c.1500–1046 BC) and the Zhou (1046–771 BC) dynasties, with their neighbours in the steppe. Intermediaries in these exchanges were disparate groups in a broad border area of relatively high land around the heart of China, the Central Plains. The societies of central China were already so advanced that, when these foreign innovations were adopted, they were transformed within highly organised social and cultural systems.
  13. ^ Bai (2003), p. 157.
  14. ^ Liu & Chen (2012), p. 234.
  15. ^ Liu (2005), p. 224.
  16. ^ JIANJUN, MEI (2003). "Cultural Interaction between China and Central Asia during the Bronze Age" (PDF). Proceedings of the British Academy. 121: 1–39. the argument for possible Afanasievo-Xinjiang contact based on the finds at the Gumugou cemetery in the north-eastern rim of the Tarim basin would seem reasonable and needs to be kept open for the future archaeological finds. In other words, the possibility for the dispersal of early copperbased metallurgy from the Eurasian steppe into Xinjiang and further east to Gansu cannot be excluded at present and will have to be considered when further archaeological evidence becomes available.
  17. ^ Lin, Meicun (2016). "Seima-Turbino Culture and the Proto-Silk Road". Chinese Cultural Relics. 3 (1–002): 241–262. doi:10.21557/CCR.48032340. ISSN 2330-5169. The discovery of the Seima-Turbino culture in China is of great importance, as it demonstrates with material evidence that Chinese metallurgy derives from the cultures of the Eurasian Steppe.
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  22. ^ Jacques Guertin; James Alan Jacobs; Cynthia P. Avakian (2005). Chromium (VI) Handbook. CRC Press. pp. 7–11. ISBN 978-1-56670-608-7.
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  34. ^ Wagner 2008, p. 230.
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Sources

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Public domain
  •  This article incorporates text from appleton's new practical cyclopedia, a publication from 1910, now in the public domain in the United States.
  •  This article incorporates text from Appleton's new practical cyclopedia: a new work of reference based upon the best authorities, and systematically arranged for use in home and school, by Marcus Benjamin, Arthur Elmore Bostwick, Gerald Van Casteel, George Jotham Hagar, a publication from 1910, now in the public domain in the United States.
  •  This article incorporates text from The universal cyclopaedia, a publication from 1900, now in the public domain in the United States.
  •  This article incorporates text from Universal cyclopædia and atlas, Volume 8, by Charles Kendall Adams, Rossiter Johnson, a publication from 1901, now in the public domain in the United States.
  •  This article incorporates text from Johnson's universal cyclopedia: a new edition, by A.J. Johnson Company, a publication from 1895, now in the public domain in the United States.
  •  This article incorporates text from Johnson's universal cyclopaedia, Volume 6, by Charles Kendall Adams, a publication from 1895, now in the public domain in the United States.
  •  This article incorporates text from Universal cyclopaedia and atlas, Volume 8, by Charles Kendall Adams, Rossiter Johnson, a publication from 1902, now in the public domain in the United States.