Peak copper

Peak copper is the point in time at which the maximum global copper production rate is reached. Since copper is a finite resource, at some point in the future new production from mining will diminish, and at some earlier time production will reach a maximum. When this will occur is a matter of dispute. Unlike fossil fuels, copper is scrapped and reused, and it has been estimated that at least 80% of all copper ever mined is still available (having been repeatedly recycled).[1]

World copper production, 1900–2012

Copper is among the most important industrial metals, ranking third after iron and aluminium in terms of quantity used.[2] It is valued for its heat and electrical conductivities, ductility, malleability and resistance to corrosion. Electrical uses account for about three quarters of total copper consumption, including power cables, data cables and electrical equipment. It is also used in cooling and refrigeration tubing, heat exchangers, water pipes and consumer products.[2]

Copper has been used by humans for at least 10,000 years. More than 97% of all copper ever mined and smelted has been extracted since 1900. The increased demand for copper due to the growing Indian and Chinese economies since 2006 has led to increased prices and an increase in copper theft.[3]

History

Concern about the copper supply is not new. In 1924 geologist and copper-mining expert Ira Joralemon warned:[4]

... the age of electricity and of copper will be short. At the intense rate of production that must come, the copper supply of the world will last hardly a score of years. ... Our civilization based on electrical power will dwindle and die.

Copper demand

Total world production is about 18 million metric tons per year.[2] Copper demand is increasing by more than 575,000 tons annually and accelerating.[3] Based on 2006 figures for per capita consumption, Tom Graedel and colleagues at Yale University calculate that by 2100 global demand for copper will outstrip the amount extractable from the ground.[5] China accounted for more than 22% of world copper demand in 2008,[6] and is nearly 40% in 2014.

For some purposes, other metals can substitute, aluminium wire was substituted in many applications, but improper design resulted in fire hazards.[7] The safety issues have since been solved by use of larger sizes of aluminium wire (#8AWG and up), and properly designed aluminium wiring is still being installed in place of copper. For example, the Airbus A380 uses aluminum wire in place of copper wire for electrical power transmission.[8]

Copper supply

Globally, economic copper resources are being depleted with the equivalent production of three world-class copper mines being consumed annually.[3] Environmental analyst Lester Brown suggested in 2008 that copper might run out within 25 years based on what he considered a reasonable extrapolation of 2% growth per year.[9]

New copper discoveries

Fifty-six new copper discoveries have been made during the three decades 1975–2005.[3] World discoveries of new copper deposits are said to have peaked in 1996.[10] However, according to the US Geological Survey (USGS), remaining world copper reserves have more than doubled since then, from 310 million metric tons in 1996[11] to 890 million metric tons in 2022.[12]

Production

Production trends in the top five copper-producing nations

As shown in the table below, the three chief national producers of copper, respectively, in 2002, were Chile, Indonesia, and the United States. In 2013, they were Chile, China, and Peru. Twenty-one of the 28 largest copper mines in the world (as of 2006) are not amenable to expansion.[3]

Copper production (thousands tonnes)[13][14][15][16][17][18][19][20][21][22][23][24]
Country 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015
 Chile 4,580 4,860 5,410 5,320 5,560 5,700 5,330 5,390 5,420 5,260 5,430 5,780 5,750 5,760
 China 585 565 620 640 890 920 950 995 1,190 1,310 1,630 1,600 1,760 1,710
 Peru 843 850 1,040 1,090 1,049 1,200 1,270 1,275 1,250 1,240 1,300 1,380 1,380 1,700
 United States 1,140 1,120 1,160 1,150 1,200 1,190 1,310 1,180 1,110 1,110 1,170 1,250 1,360 1,380
 Australia 873 870 854 930 859 860 886 854 870 958 958 990 970 971
 Congo-Kinshasa N/A N/A N/A N/A N/A N/A N/A N/A 343 520 600 970 1,030 1,020
 Russia 695 700 675 675 725 730 750 725 703 713 883 833 742 732
 Zambia 330 330 427 450 476 530 546 697 690 668 690 760 708 712
 Canada 600 580 546 580 607 585 607 491 525 566 579 632 696 697
 Indonesia 1,160 1,170 840 1,050 816 780 651 996 872 543 360 504 N/A N/A
 Mexico 330 330 406 420 338 400 247 238 260 443 440 480 515 594
 Kazakhstan 490 480 461 400 457 460 420 390 380 417 424 446 N/A N/A
 Poland 503 500 531 530 512 470 430 439 425 427 427 429 N/A N/A
Other countries 1,500 1,500 1,610 1,750 1,835 1,800 2,030 2,190 1,900 1,970 2,000 2,200 3,600 3,800
 World 13,600 13,800 14,700 15,000 15,100 15,500 15,600 16,100 16,100 16,100 16,900 18,200 18,400 19,100

Reserves

Copper is a fairly common element, with an estimated concentration of 50–70 ppm (0.005–0.007 percent) in Earth's crust (1 kg of copper per 15–20 tons of crustal rock).[25] A concentration of 60 ppm would multiply out to 1.66 quadrillion tonnes over the 2.77×1022 kg mass of the crust,[26] or over 90 million years' worth at the 2013 production rate of 18.3 MT per year. However, not all of it can be extracted profitably at the current level of technology and the current market value.

The USGS reported a current total reserve base of copper in potentially recoverable ores of 1.6 billion tonnes as of 2005, of which 950 million tonnes were considered economically recoverable.[27] A 2013 global assessment identified "455 known deposits (with well-defined identified resources) that contain about 1.8 billion metric tons of copper", and predicted "a mean of 812 undiscovered deposits within the uppermost kilometer of the earth's surface" containing another 3.1 billion metric tons of copper "which represents about 180 times 2012 global copper production from all types of copper deposits."[28]

Copper reserves (thousands of tonnes)[21][29]
Country 1996 Reserves Percent 2015 Reserves Percent
 Chile 88,000 28.4% 209,000 29.9%
 Australia 7,000 2.26% 93,000 13.2%
 Peru 7,000 2.26% 68,000 9.71%
 Mexico N/A N/A 38,000 5.43%
 United States 45,000 14.5% 35,000 5.00%
 China 3,000 0.968% 30,000 4.29%
 Russia 20,000 6.45% 30,000 4.29%
 Poland 20,000 6.45% 28,000 4.00%
 Indonesia 11,000 3.55% 25,000 3.57%
 Congo-Kinshasa N/A N/A 20,000 2.86%
 Zambia 12,000 3.87% 20,000 2.86%
 Canada 11,000 3.55% 11,000 1.57%
 Kazakhstan 14,000 4.52% 6,000 0.86%
 Zaire 11,000 3.55% N/A N/A
 Philippines 7,000 2.26% N/A N/A
Other countries 55,000 17.7% 90,000 12.9%
 World 310,000 100% 700,000 100%

Recycling

In the US, more copper is recovered and put back into service from recycled material than is derived from newly mined ore. Copper's recycle value is so great that premium-grade scrap normally has at least 95% of the value of primary metal from newly mined ore.[30] In Europe, about 50% of copper demand comes from recycling (as of 2016).[31]

As of 2011, recycled copper provided 35% of total worldwide copper usage.[32]

Undiscovered conventional resources

Based on discovery rates and existing geologic surveys, researchers estimated in 2006 that 1.6 billion metric tons of copper could be brought into use. This figure relied on the broadest possible definition of available copper as well as a lack of energy constraints and environmental concerns.[27]

The US Geological Survey estimated that, as of 2013, there remained 3.5 billion metric tons of undiscovered copper resources worldwide in porphyry and sediment-hosted type deposits, two types which currently provide 80% of mined copper production. This was in addition to 2.1 billion metric tons of identified resources. Combined identified and estimated undiscovered copper resources were 5.6 billion metric tons,[33] 306 times the 2013 global production of newly mined copper of 18.3 million metric tons.

Unconventional resources

Deep-sea nodules are estimated to contain 700 million tonnes of copper.[15]

Copper prices

Price of copper, 1959–2022

The international price of copper struck a first peak level on 6 March 2008, on the London Metal Exchange (LME), surging 5.8% over the previous trading day to US$4.02 per pound. The previous record was set on 12 May 2006, at US$3.98/lb. The price increased rapidly in early 2008, rising 23% in February 2008,[34] then declined 40% before December 2008,[35] and reached US$1.30 by year's end.[36] In February 2011 the price peaked at US$4.58/lb[37] but then fell to US$3.18/lb during 2013.


Criticism

Julian Simon was a senior fellow at the Cato Institute and a professor of business and economics. In his book The Ultimate Resource 2 (first printed in 1981 and reprinted in 1998), he extensively criticizes the notion of "peak resources", and uses copper as one example. He argues that, even though "peak copper" has been a persistent scare since the early 20th century, "known reserves" grew at a rate that outpaced demand, and the price of copper was not rising but falling over the long run. For example, even though world production of copper in 1950 was only one-eighth of what it was in the early 2000s, known reserves were also much lower at the time – around 100 million metric tons – making it appear that the world would run out of copper in 40 to 50 years at most.

Simon's own explanation for this development is that the very notion of known reserves is deeply flawed,[38] as it does not take into account changes in mining profitability. As richer mines are exhausted, developers turn their attention to poorer sources of the element and eventually develop cheap methods of extracting it, raising known reserves. Thus, for example, copper was so abundant 5000 years ago, occurring in pure form as well as in highly concentrated copper ores, that prehistoric peoples were able to collect and process it with very basic technology. As of the early 21st century, copper is commonly mined from ores that contain 0.3–0.6% copper by weight. Yet, despite the material being far less widespread, the cost of, for example, a copper pot was vastly lower in the late 20th century than 5000 years ago.[39]

See also

References

  1. "Copper Recycling". Copper Alliance. 2021. Retrieved 8 February 2023.
  2. National Minerals Information Center. "Copper Statistics and Information". United States Geological Survey. Retrieved 8 February 2023.
  3. Leonard, Andrew (2 March 2006). "Peak copper?". Salon. Retrieved 23 March 2008.
  4. "Copper and electricity to vanish in twenty years?". Engineering and Mining Journal. 118 (4): 122. 26 July 1924.
  5. David Cohen (23 May 2007). "Earth's natural wealth: an audit". New Scientist (2605): 34–41. Archived from the original on 20 July 2008. Retrieved 9 April 2008.
  6. Glaister, Dan; Branigan, Tania & Bowcott, Owen (20 March 2008). "Deaths and disruption as price rise sees copper thefts soar". The Guardian. Retrieved 9 April 2008.
  7. http://www.cpsc.gov//PageFiles/118856/516.pdf
  8. Hellemans, Alexander (1 January 2007). "Manufacturing Mayday: Production glitches send Airbus into a tailspin". IEEE Spectrum. Retrieved 19 June 2014.
  9. Brown, Lester (2006). Plan B 2.0: Rescuing a Planet Under Stress and a Civilization in Trouble. New York: W.W. Norton. p. 109. ISBN 0-393-32831-7.
  10. "Peak Copper Means Peak Silver". Charleston Voice. 29 December 2005. Archived from the original on 4 November 2013. Retrieved 9 April 2008.
  11. Edelstein, Daniel L. (February 1997). "Copper" (PDF). Mineral Commodity Surveys. U.S. Geological Survey. p. 53. Retrieved 8 February 2023.
  12. Flanagan, Daniel M. (January 2023). "Copper" (PDF). Mineral Commodity Surveys. U.S. Geological Survey. p. 2. Retrieved 8 February 2023.
  13. "pg. 54 – Copper" (PDF). USGS. 2004. Retrieved 9 April 2008.
  14. "pg. 56 – Copper" (PDF). USGS. 2006. Retrieved 9 April 2008.
  15. "pg. 54 – Copper" (PDF). USGS. 2008. Retrieved 9 April 2008.
  16. "pg. 49 – Copper" (PDF). USGS. 2010. Retrieved 15 July 2012.
  17. "pg. 49 – Copper" (PDF). USGS. 2011. Retrieved 29 March 2015.
  18. "pg. 49 – Copper" (PDF). USGS. 2012. Retrieved 15 July 2012.
  19. "pg. 49 – Copper" (PDF). USGS. 2013. Retrieved 29 March 2015.
  20. "pg. 48 – Copper" (PDF). USGS. 2014. Retrieved 11 April 2014.
  21. "pg. 49 – Copper" (PDF). USGS. 2015. Retrieved 29 March 2015.
  22. "pg. 55 – Copper" (PDF). USGS. 2016. Retrieved 29 March 2017.
  23. "pg. 55 – Copper" (PDF). USGS. 2017. Retrieved 29 March 2017.
  24. "Copper Statistics". USGS. 2016. Retrieved 29 March 2017.
  25. Emsley, John (2003). Nature's building blocks: an A–Z guide to the elements. Oxford University Press. pp. 121–125. ISBN 978-0-19-850340-8.
  26. Peterson, B. T.; Depaolo, D. J. (December 2007). Mass and Composition of the Continental Crust Estimated Using the CRUST2.0 Model. American Geophysical Union Fall Meeting Abstracts. Bibcode:2007AGUFM.V33A1161P. V33A–1161.
  27. Biello, David (17 January 2006). "Measure of Metal Supply Finds Future Shortage". Scientific American. Retrieved 23 March 2008.
  28. Hammarstrom, Jane M. (29 October 2013). "Undiscovered Porphyry Copper Resources—A Global Assessment". The Geological Society of America: Annual Meeting & Expo. Retrieved 12 April 2014.
  29. "pg. 50 – Copper" (PDF). USGS. 1996. Retrieved 12 April 2014.
  30. "Copper in the USA: Bright Future – Glorious Past". Copper Development Association. Retrieved 9 April 2008.
  31. Europe’s Copper Industry
  32. International Copper Study Group, The World Copper Factbook 2012, p. 50, retrieved 8 February 2023
  33. Kathleen M. Johnson and others, Estimate of undiscovered copper resources of the world, 2013, US Geological Survey, Fact Sheet 2014–3004, Jan. 2014.
  34. "International copper price hits record high". China View. 8 March 2008. Archived from the original on 20 March 2008. Retrieved 9 April 2008.
  35. Jha, Dilip Kumar (30 November 2008). "Falling demand may dent base metal prices". Business Standard India. Retrieved 8 February 2023.
  36. $1.30 price. Charts3.barchart.com. Retrieved on 14 March 2014.
  37. London Metal Exchange: Copper Archived 5 March 2011 at the Wayback Machine. LME.com. Retrieved on 14 March 2014.
  38. Simon, Julian (16 February 1998) Chapt 12, "People, Materials, and Environment" in The Ultimate Resource II.
  39. Simon, Julian (1998). "The Ultimate Resource II: People, Materials, and Environment". Retrieved 8 February 2023.
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