base metals
What Are Technology Metals?
So, just what are “technology metals’? As a relatively new term, coined by Jack Lifton in 2007 and now widely used in the industry, there are probably a number of alternative definitions out there. Here at TMR, we say that the technology metals are those generally-rare metals that are essential for the production of ‘high tech’ devices and engineered systems, such as:
- The mass production of miniaturized electronics and associated devices;
- Advanced weapons systems and platforms for national defense;
- The generation of electricity using ‘alternative’ sources such as solar panels and wind turbines;
- The storage of electricity using cells and batteries.
There are of course numerous other uses and applications of these metals.
Almost all technology metals are byproducts of the production of base metals, with the exception of the rare earth metals, as a group, and lithium.
Prior to World War II, there were many metals for which there were no practical uses. They were literally laboratory curiosities available only in small quantities, obtained at high costs in both time and money. For this reason, they were called the ‘minor metals’; they simply had no major uses in contrast to the base metals and even to the precious metals. It didn’t matter how abundant a metal actually was in nature; if it had no practical uses it simply wouldn’t be produced. Nickel, for example, was a ‘minor metal’ before the commercial development of stainless steel in 1919, when economical methods of mass producing and using stainless steel were undertaken in earnest. Nickel after that rapidly became a high volume production metal.
In the first few years of the 20th Century, malleable tungsten was developed at General Electric and it rapidly displaced all other materials for use as filaments in incandescent light bulbs. Tungsten production increased, and shortly thereafter tungsten steels were developed and used, at first for military armor and armor piercing projectiles. Tungsten carbide for cutting tools soon after that revolutionized precision machining, just in time to make mass produced engines a reality. Tungsten, a minor metal in 1900, became by 1918 an important industrial metal, and had the designation ‘technology metal’ existed in 1918, tungsten would surely have been recognized as such at that point.
As an example of a more well-known metal transitioning from ‘minor’ to ‘major’ status, look at the late 19th Century minor metal aluminum, which was used to cap the Washington Monument in 1886, as a symbol of America’s wealth. Aluminum was then more expensive than gold. Keep in mind that only a lunatic or a visionary would have predicted in 1886, that common people would cook with aluminum pots and pans less than a century later, and that even in 1919 the idea of nickel stainless steel kitchen appliances for the masses would have been considered fantasy nonsense.
World War II transformed a sleepy academic discipline, the study of the physical properties of all of the metals, into modern metallurgy with its emphasis on developing end uses for metals based not just on their properties as structural materials but even more important, on their newly categorized electrical, electronic, and magnetic properties for use in technology.
Fifty years ago, it was unclear which, if any of the then minor metals would be most useful for practical mass producible technologies. We were then only just discovering and, actually, determining which of the electronic and magnetic properties of the chemical elements were important to our civilization’s needs and desires. Prior to World War I, only the structural, decorative, simple electrical transmission and storage, and monetary metals were well known even to the metallurgists of the day. The last naturally occurring metal to be discovered was rhenium and that was only in 1924. What no one knew between the wars was that it would be important to know which, if any, of the little used minor metals could in fact be produced in significant volume at a significant yearly rate of production. There was no need for any such information, certainly not in academia, where most of these studies would be then undertaken. The equation was simple; no use equals no demand and therefore no attempt to supply in quantity.
World War II was the single most important driver for the transformation of the minor metals into the technology metals. Economics as a limitation to innovation was put aside and national security became the only driver for the development of the technologies for jet and rocket engines, radio and radar, electronic computing, and super weapons.
A glittering galaxy of physicists and innovative engineers, perhaps a once in a thousand years gathering of intellects, told the chemical engineers who specialized in metallurgy, which metals they critically needed in abundance and the world’s governments told all of them not to consider economics in their quest to produce them. The chemical engineers then began systematically to learn how to find, refine, and mass produce the formerly minor metals, now desperately needed for war technology. Among others this lead to the production for the first time, in every case, of large quantities of previously never-before-seen ultra pure silicon and germanium, as well as high purity gallium and indium, uranium and thorium, and mixed, and some individually separated, rare earth metals and, just after the war, of lithium.
After the hot part of World War II ended, a 50 year long Cold War immediately ensued, during which the postwar uneconomic overproduction of minor metals for the new technologies continued, and the increasingly surplus production was diverted to high volume civilian consumer uses, spun off from technologies developed for the military on a cost plus basis. This was the seeding of our modern ‘Age of Technology.’ Its original economics were synthetic; the critical materials for modern technologies were being produced from operations and sources the development of which had been fully subsidized, in an unprecedented open-ended hand out by the war economy, both cold and hot.
So, at the same time, today, that we have become totally dependent on the technology metals for the mass production of necessary consumer goods such as miniaturized electronics, large scale television and cinema displays, electronic data processing, and personal communications,. i.e., our way of life, we are also critically dependent on technology metals for our national security in the form of secure communications, weapons guidance, surveillance, and battlefield superiority. The problem is that the bulk of the technology metals is now used for civilian production and the military instead of catalyzing the supply and taking a priority position, is now simply another customer.
In the table below we list those metals that we define as ‘rare’, by defining rare as ‘produced annually in a quantity of 25,000 metric tonnes or less.’ Only the most obscure of these rare metals, such as the rare earths holmium, ytterbium, and lutetium, can still be defined as minor metals, because even today they only have minor uses since they are and will remain too rare ever to be available in sufficient quantity for mass production of a technology.
| Metal | Production [tonnes] |
|---|---|
| Cobalt | 62,000 |
| Uranium | 35,332 |
| Lanthanum | 32,860 |
| Silver | 21,332 |
| Neodymium | 19,096 |
| Cadmium | 18,000 |
| Lithium | 18,000 |
| Yttrium | 8,900 |
| Bismuth | 7,300 |
| Praseodymium | 6,150 |
| Gold | 2,350 |
| Dysprosium | 2,000 |
| Selenium | 1,500 |
| Samarium | 1,364 |
| Zirconium | 1,230 |
| Gadolinium | 744 |
| Indium | 600 |
| Terbium | 450 |
| Europium | 272 |
| Palladium | 195 |
| Platinum | 178 |
| Germanium | 140 |
| Gallium | 78 |
| Rhenium | 52 |
| Rhodium | 30 |
| Hafnium | 25 |
| Tantalum | 0 |
| Erbium | UNKNOWN |
| Holmium | UNKNOWN |
| Lutetium | UNKNOWN |
| Scandium | UNKNOWN |
| Tellurium | UNKNOWN |
| Thorium | UNKNOWN |
| Thulium | UNKNOWN |
| Ytterbium | UNKNOWN |
The technology metals are almost all rare metals, and they are almost all produced as byproducts of base or common metals.
The problem with the technology metals is that our supply of them, or more specifically our maximum rates of production of them, is critically dependent mostly upon our production of base metals. In the case of the rare earth metals, mined as a group, the key supply issue is the complex metallurgy of the separation of the individual rare earths from each other; for the case of lithium, a key issue is the length of time that primary concentration takes. The rare earths as a group are actually not rare, based on the admittedly arbitrary definition above, though individual rare earths certainly are.
The rare earths and lithium are today the subject of much discussion, because they have become the most visible technology metals. The definition of a rare metal is somewhat fluid; a few of today’s rare metals may not always be so. Lithium, for example, is on the cusp of being struck from the list of rare metals, because of its use in electrical storage. But it has turned out that once a minor metal becomes a technology metal, it will never again be a minor metal.
Source: http://www.techmetalsresearch.com/what-are-technology-metals/
China Will Continue to Dominate the Rare Earths Market in 2011
Editor’s Note: Prices for many precious and base metals hit record highs in 2010, as economic uncertainty rattled around the globe. What does 2011 hold for gold, silver, platinum, palladium, copper and other metals? Kitco News reporters have prepared a series of stories which examine what is in store for 2011, not only for metals but for currencies, stocks and the overall economy. These stories will be posted on Kitco.com during the holiday period and also will be featured in a special section. Stay tuned for video highlights as well.
(Kitco News) - China’s dominance of global rare earths output will continue in 2011, yet at the same time other nations are starting to make preparations to pull more metal from the ground and reduce China’s stranglehold on the market in future years.
Until the last few months, the mention of rare earth metals likely would elicit a blank stare unless the conversation involved someone in a specific sector that uses the elements.
Rare earth metals, known as REEs, burst into the mainstream media limelight during the past several months, with articles in The New York Times, The Wall Street Journal, the Financial Times, on major wire services and televised segments on CNBC. The big exposure came with a flap that developed when China, which controls 95% to 97% of the current REE global output, stopped exporting to the Japanese.
Fears continue over the supply of rare earth metals, which consist of 17 elements used in creating a variety of consumer, environmental and industrial-driven technological products. Despite some movement expected in 2011 and beyond to develop greater supply from other global sources, the Chinese still hold the shovel.
“They have the ability to dictate the market if they want to,” said Charl Malan, senior metals and mining analyst at Van Eck Global. The company offers a number of metals-related investments and this fall started the first U.S.-listed exchange-traded fund for equities of companies involved with producing, refining and recycling rare earth/strategic metals.
“With rare earths growth in the next five years about 225,000 tons, that’s about 9% (year-on-year) growth number,” Malan said. “Currently, supply is about 125,000 tons, out of which China produces about 120,000 tons.”
Major importers have come to depend on China due to its ability to manufacture REEs at a reasonable cost. The embargo China placed on exports to Japan has been devastating to the Japanese and shows the strength of the REE demand China commands. Japan was the leading importer of REEs.
“News out of China is a big part of it,” said The Mercenary Geologist Mickey Fulp. “It is a purely speculative sector. As news comes out of China about export quotas, relaxing export quotas or news of any kind on that regard supply and demand fundamentals of the rare earth elements sector is going to affect prices.”
Fulp said China controls well over 90% of the current supply. The dominance is mainly because the Chinese have developed the ability to manufacture these minerals in such a way that the rest of the world could be falling behind quickly, not because rare earth metals are really that rare.
“For me, if I look at the bigger picture for rare earths, this is what’s essential,” Malan of Van Eck said. “There’s an abundance of rare earths around the world. It’s not so much the mining, it’s the fact we don’t have the manufacturing capacity and we don’t have the skill sets or the equipment. That’s my biggest concern.”
Malan believes that China has invested its resources in such a way that it is now properly positioned for the future in terms of manufacturing capacity, but more importantly, well placed from a knowledge standpoint.
“To have the refined product really work, you obviously need very highly educated, highly skilled people specifically within an industry,” Malan said. “There’s something like 800 people with Ph.D.s specifically linked to rare earths. They don’t just focus on the equipment, the processing and the manufacturing side of it but also the manpower and the knowledge base behind it.”
A half century ago China was not among the leading producers of REEs. Between 1950 and 1980, the U.S., India, South Africa and Brazil were considered to be the front-runners in production. During the 1980s, China began underselling competitors, leading to consumers purchasing cheap supply from the Chinese.
This had a negative effect on REE mines in several countries, leading to most being shut down. Molycorp Minerals mine in California was once the largest REE producer in the world but was forced to close in 2002. The mine is set to reopen in 2011 and should begin contributing production by 2012.
“In 2012, there will be additional supply from Molycorp which will be 20,000 (metric) tons,” said Marino G. Pieterse, publisher and editor of Gold Letter International, Uranium Letter International and Rare Earths Elements International.
Molycorp is not the only rare earths company beginning REE production in the next few years.
“In 2013 you’ll have three other companies that will begin producing REEs,” Pieterse said. “Frontier Rare Earths will produce 10-20,000 (metric) tons, Greenland Minerals and Earths LTD will have 40,000 (metric) tons and then there’s Rare Elements Resources LTD, which will have 20,000 (metric) tons.”
Lynas Corporation in Australia is also slated to begin REE production, with tonnage reaching over 20,000.
Analysts said that the move towards wider production could mean there will be an over-supply of REEs by 2014-2015, which will bring stability to prices.
Despite the title of being rare, REEs are in abundance. With countries other than China developing the means to manufacture these metals coupled with the need to introduce and maintain greener technologies, REEs are expected to perform well in the coming years.
“I see bigger and better things for the entire sector,” Fulp said.
——
Scandium
Aluminum alloy: aerospace
Yttrium
Phosphors, ceramics, lasers
Lanthanum
Re-chargeable batteries
Cerium
Batteries, catalysts, glass polishing
Praseodymium
Magnets, glass colorant
Neodymium
Magnets, lasers, glass
Promethium
Nuclear batteries
Samarium
Magnets, lasers, lighting
Europium
TV color phosphors: red
Gadolinium
Superconductors, magnets
Terbium
Phosphors: green, fluorescent lights
Dysprosium
Magnets, lasers
Holmium
Lasers
Erbium
Lasers, vanadium steel
Thulium
X-ray source, ceramics
Yterrbium
Infrared lasers, high reactive glass
Lutetium
Catalyst, PET scanners
Forget oil, Indium may be the next most precious resource
by Thomas J Thompson on October 30, 2010
Indium Ingots
I will grant you that Indium finger isn’t a good title for a Bond movie, but Indium may certainly be worth hoarding.
Let’s start with the basics. Indium is a chemical element with chemical symbol In and atomic number 49. It is rare, very soft, malleable and is easily fusible. It is a post-transitional metal that is chemically similar to aluminum or gallium. Zinc ores are the primary source of indium and is named for the indigo blue line in its spectrum that was the first indication of its existence in ores, as a new and unknown element.
Heres why it’s important today’s mobile touchscreen gadgets, along with all liquid crystal displays, rely on it, and it could be gone within the decade.
Indium is the principal component in indium tin oxide (ITO). ITO has unique qualities that make it unique. It is a rare example of a material that is both electrically conducting and optically transparent, which means it does not absorb photons of light. Absorption occurs when a photon’s energy matches that needed to knock an electron into an excited state. In a metallic conductor, where there is a free-flowing “sea” of electrons with many different energy states, his almost always happens. Accordingly, almost all metals are highly absorbing and entirely opaque. Not so ITO. It is transparent like glass, but also conducts.
ITO changed the way touchscreen works. The common methods, prior to ITO, were to use infrared LEDs ranged around the screen to fire beams that are blocked by a touch, but those were bulky and required a lot of power to run; or to use a stylus and two layers of ITO separated by a slight gap. Tapping this resistive screen with the stylus brought the two layers together, allowing a current to pass. New touchscreen devices utilize the fact that your finger is conductive to do away with the stylus. Touching the screen changes its capacitance at that location, a change picked up by a single layer of ITO.
The problem is that no one is sure how much indium there is left. The US Geological Survey estimates that known reserves of indium worldwide amount to 16,000 tons (63% in China). At the current rate of consumption, those reserves will be exhausted by 2020. Those numbers donât take into account recycling or any new sources of indium. According to Indium Corporation, the largest processor of indium, claims that, on the basis of increasing recovery yields during extraction, recovery from a wider range of base metals (including tin, copper and other polymetallic deposits) and new mining investments, the long-term supply of indium is sustainable, reliable and sufficient to meet increasing future demands.
According to James Mitchell Crow writing in New Scientist magazine, the increasing demands for ITO promise to make ITO rare and, therefore, more expensive. The touchscreen market is currently projected at $1.47 billion and will balloon to $2.5 billion by 2017. This means that the race to find a replacement for ITO are on! Some of the replacements under consideration are zinc oxide, but it’s not as conductive, transparent or physically resilient as ITO. Another consideration is to stretch the current reserves of indium by mixing it with cadmium oxide. Doing so may reduce the amount of indium necessary per screen by 80%. Unfortunately, cadmium is highly toxic and prone to cracking. More futuristic thoughts include the development of conducting polymers, but these are often prone to ultraviolet light and oxygen.
So is it the end of the touchscreen era? Probably not thanks to nanotechnology.
One solution may be carbon nanotubes. Carbon is a chemical chameleon. In some guises, it is the most light-absorbing material known. Pare it down to nanoscale structures, however, and it becomes transparent. Carbon nanotubes are essentially graphene sheets rolled up into tiny cylinders. Graphene, the wonder material behind the award of this year’s Nobel prize in physics, consists of sheets of graphite just a single atom thick. The problem is that individual nanotubes are highly conductive, but the electrons racing across their surface stop dead when they get to the end of a nanotube and have to jump to the next.
Another idea may be metal nanowires. Experiments with silver nanowires have shown transparency of 85 percent and a conductivity only a fraction behind that of ITO. Unfortunately, silver nanowires are 10 times as expensive to produce as top-grade ITO. Other concepts include a mechanical switch behind every pixel, registering the force as the screen is touched, but using pressure-sensing technology means doing away with the protective glass cover, making it more susceptible to damage. Another possibility is an optical technology that incorporates a light-detecting element into each pixel. These light sensors turn the screen into a scanner that can detect and follow a finger. However, it needs significant processing power to continually analyze the screen surface and works only a quarter as fast as a traditional laptop touchpad.
In any case, such innovations do not address the more fundamental problem that, touch or no touch, the electrodes that supply power to the pixels of LCD displays themselves depend on ITO. That will be solved only by the development of new materials that mimic ITO’s intensely desirable combination of transparency and conductivity.
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